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USER’S GUIDE

SewerCAD v5
for Windows

1986−2001 Haestad Methods, Inc. All rights reserved.
SewerCAD v5 User’s Guide (Second Printing)

This book is published by Haestad Methods, Inc. and is intended for civil engineers and hydraulic modelers
(including professional engineers, technicians, and students). This book may not be copied, photocopied,
reproduced, translated, or converted to any electronic or machine-readable form in whole or in part without
prior written approval of Haestad Methods, Inc.
Trademarks
The following are registered trademarks of Haestad Methods, Inc:
CulvertMaster, Cybernet, FlowMaster, PondPack, SewerCAD, StormCAD, and WaterCAD.
The following are trademarks of Haestad Methods, Inc:
HECPack, POND-2, Graphical HEC-1, Graphical HEC-Pack.
Haestad Methods is a registered tradename of Haestad Methods, Inc.
AutoCAD is a registered trademark of Autodesk, Inc.
ESRI is a registered trademark of Environmental Systems Research Institute, Inc.
All other brands, company or product names, or trademarks belong to their respective holders.

37 Brookside Rd.
Waterbury, CT 06708-1499
Voice: +1 - (203) 755-1666
FAX: +1 - (203) 597-1488
e-mail: [email protected]
Internet: http://www.haestad.com

Table of Contents

i

Table of Contents
Preface

xiii

Welcome to SewerCAD

Chapter 1 Orientation

xiii

1

1.1

What is SewerCAD?

1

1.2

When to Use SewerCAD?

1

1.3

What's New in SewerCAD?

2

1.4

Installation, Upgrades and Updates
1.4.1
Minimum System Requirements
1.4.2
Installing Haestad Methods' Products
1.4.3
Uninstalling Haestad Methods' Products
1.4.4
Troubleshooting Setup or Uninstall
1.4.5
Software Registration
1.4.6
Upgrades
1.4.7
Globe Button
1.4.8
Network Licensing

3
3
4
4
4
5
5
5
6

1.5

Learning SewerCAD
1.5.1
SewerCAD Documentation
1.5.2
How to Use Help
1.5.3
How Do I?
1.5.4
Glossary
1.5.5
Tutorials
1.5.6
Sample Projects
1.5.7
Haestad Methods Workshops and Certification

9
9
9
9
10
10
10
10

1.6

Contacting Haestad Methods
1.6.1
Sales
1.6.2
Technical Support
1.6.3
Your Suggestions Count
1.6.4
How to Contact Us

11
11
11
12
12

Chapter 2 SewerCAD Main Window

13

2.1

Overview

13

2.2

Main Window Components
2.2.1
Stand-Alone Mode, AutoCAD Mode
2.2.2
SewerCAD Main Windows
2.2.3
Drawing Pane
2.2.4
Status Pane
2.2.5
Menus, Toolbars, and Shortcut Keys
2.2.6
Command Line

13
13
13
15
15
16
16

2.3

SewerCAD Menus
2.3.1
Pull-down Menus
2.3.2
File Menu
2.3.3
Edit Menu
2.3.4
Analysis Menu
2.3.5
View Menu
2.3.6
Tools Menu

17
17
17
19
21
21
22

ii

Table of Contents
2.3.7
2.3.8
2.3.9

Report Menu
Draw Menu (in AutoCAD Mode Only)
Help Menu

24
25
25

2.4

SewerCAD Toolbars
2.4.1
Toolbar Button Summaries
2.4.2
Tool Pane Summary
2.4.3
SewerCAD Tool Palette
2.4.4
Analysis Toolbar
2.4.5
SewerCAD VCR Controls
2.4.6
Other Toolbar Buttons

26
26
26
28
28
28
29

2.5

The Status Bar
2.5.1
General Status Information
2.5.2
DXF Background Status
2.5.3
Cursor Location
2.5.4
Calculation Results Status
2.5.5
File Status

30
30
30
30
31
31

Chapter 3 Quick Start Lessons

33

3.1

Overview

33

3.2

Lesson 1 - Creating a Schematic Network

33

3.3

Lesson 2 - Automatic Design

43

3.4

Lesson 3 - Scenario Management

45

3.5

Lesson 4 - Presentation of Results

50

3.6

Lesson 5 - Running an Extended Period Simulation

56

Chapter 4 Starting a SewerCAD Project

63

4.1

Overview

63

4.2

File Management
4.2.1
Multiple Sessions

63
63

4.3

Project Management
4.3.1
Project Setup Wizard
4.3.2
Project Summary

63
63
64

4.4

Options
4.4.1
Global Options
4.4.2
Project Options
4.4.3
Drawing Options

64
64
66
67

4.5

FlexUnits
4.5.1
FlexUnits Overview
4.5.2
Field Options
4.5.3
Units
4.5.4
Display Precision
4.5.5
Scientific Notation
4.5.6
Minimum and Maximum Allowed Value
4.5.7
FlexUnits Manager

69
69
69
70
70
70
70
71

4.6

Quick Attribute Selector

71

Chapter 5 Layout and Editing Tools
5.1

Graphical Editor Overview

73
73

Table of Contents

iii

5.2

Graphical Editor
5.2.1
Using the Graphical Editor
5.2.2
Working with Network Elements Within the Graphical Editor
5.2.3
Creating New Elements
5.2.4
Changing the Pipe Layout Tool to Insert a Different Type of Node
5.2.5
Morphing Elements
5.2.6
Splitting Pipes
5.2.7
Selecting Elements
5.2.8
Editing Elements
5.2.9
Moving Elements
5.2.10
Deleting Elements
5.2.11
Other Tools

73
73
73
74
74
74
75
75
76
76
77
77

5.3

Selection Sets
5.3.1
Selection Set Manager
5.3.2
New Selection Set
5.3.3
Selection Set Dialog
5.3.4
Duplicate Selection Set
5.3.5
Delete Selection Set
5.3.6
Rename Selection Set
5.3.7
Selection Set Notes

77
78
78
78
78
78
78
78

5.4

Find Element

78

5.5

Zooming
5.5.1
Zoom Center
5.5.2
Aerial View

79
79
80

5.6

Drawing Review
5.6.1
Selection Tolerance

80
81

5.7

Relabel Elements
5.7.1
Relabel Operations
5.7.2
Elements Selected

82
82
83

5.8

Element Labeling

83

5.9

Quick View

84

Chapter 6 Hydraulic Element Editors

85

6.1

Overview

85

6.2

Element Editors
6.2.1
Using Element Editors
6.2.2
Manholes
6.2.3
Junction Chambers
6.2.4
Wet Wells
6.2.5
Pumps
6.2.6
Pressure Junctions
6.2.7
Outlets
6.2.8
Gravity Pipes
6.2.9
Pressure Pipes

86
86
86
87
87
87
88
88
88
89

6.3

Element Editors' Tabs
6.3.1
General Tab
6.3.2
Headlosses Tab
6.3.3
Diversion Tab
6.3.4
Controls Tab
6.3.5
Profile Tab
6.3.6
Design Tab
6.3.7
Section Tab

89
89
99
100
101
103
104
105

iv

Table of Contents
6.3.8
6.3.9
6.3.10
6.3.11
6.3.12

Loading Tab
Infiltration Tab
Cost Tab
User Data Tab
Message Tab

107
108
109
110
111

6.4

Loading Dialogs
6.4.1
Add New Load Dialog
6.4.2
Base Load Dialog
6.4.3
Hydrograph Dialog
6.4.4
Pattern Load Dialog

111
111
112
112
112

6.5

Prototypes

113

6.6

User Data Extensions
6.6.1
User Data Extensions Dialog

113
113

Chapter 7 FlexTables

117

7.1

Tabular Reporting Overview

117

7.2

Table Manager
7.2.1
Creating New Tables
7.2.2
Two Row Tables
7.2.3
Editing Tables
7.2.4
Duplicating Tables
7.2.5
Deleting Tables
7.2.6
Renaming Tables
7.2.7
Resetting Tables

117
118
118
118
118
118
118
119

7.3

Table Setup Dialog
7.3.1
Table Type
7.3.2
Available Table Columns
7.3.3
Selected Table Columns
7.3.4
Table Manipulation Buttons
7.3.5
Allow Duplicate Columns

119
119
120
120
120
120

7.4

Table Window
7.4.1
Editing Tables
7.4.2
Sorting/Filtering Tables
7.4.3
Table Customization
7.4.4
Table Output

120
121
122
124
126

Chapter 8 Scenarios and Alternatives

127

8.1

Overview

127

8.2

Alternatives
8.2.1
Alternatives Manager
8.2.2
Alternatives Editor
8.2.3
Physical Properties Alternative Editor
8.2.4
Sanitary (Dry Weather) Loading Alternative Editor
8.2.5
Infiltration and Inflow Loading Alternative Editor
8.2.6
Known Flow Loading Alternative Editor
8.2.7
Structure Headlosses Alternative Editor
8.2.8
Boundary Conditions Alternative Editor
8.2.9
Design Constraints Alternative Editor
8.2.10
Initial Settings Alternative Editor
8.2.11
Operational Alternative Editor
8.2.12
Cost Alternative Editor

127
128
129
130
133
134
135
135
136
136
138
139
139

Table of Contents
8.2.13
8.3

v
User Data Alternative Editor

Scenarios
8.3.1
Scenario Selection
8.3.2
Editing Scenarios
8.3.3
Scenario Manager
8.3.4
Scenario Wizard
8.3.5
Scenario Editor

Chapter 9 Modeling and Design Capabilities

139
139
140
140
140
142
144

147

9.1

Calculate
9.1.1
Calculation Type Section
9.1.2
Steady State Section
9.1.3
Extended Period Section

147
147
147
148

9.2

Calculations Options
9.2.1
Gravity Hydraulics Tab
9.2.2
HEC-22 Tab
9.2.3
AASHTO Tab
9.2.4
Generic Structure Loss Tab
9.2.5
Convex Routing Tab
9.2.6
Steady State Loading Options Tab
9.2.7
Pressure Hydraulics Tab

148
148
149
150
150
151
151
151

9.3

Pattern Manager
9.3.1
Patterns
9.3.2
Pattern Manager
9.3.3
Pattern Editor
9.3.4
Pattern Graph and Report

152
152
153
154
155

9.4

Pattern Setup Manager
9.4.1
Pattern Setup Editor

155
155

9.5

Extreme Flow Setup Manager
9.5.1
Extreme Flow Setup Editor

156
156

9.6

Default Design Constraints
9.6.1
Gravity Pipe Tab
9.6.2
Default Constraints Section
9.6.3
Extended Design Section
9.6.4
Gravity Structure Tab

157
157
157
157
158

Chapter 10 Cost Estimating

159

10.1

Overview

159

10.2

Cost Manager
10.2.1
Cost Manager - Button Section
10.2.2
Cost Manager - Center Pane
10.2.3
Cost Manager - Left Pane
10.2.4
System Cost Adjustments Table

159
160
160
161
161

10.3

Unit Cost Functions
10.3.1
Unit Cost Functions Manager
10.3.2
Tabular Unit Cost Function
10.3.3
Formula Unit Cost Function
10.3.4
Unit Cost Function Notes

161
161
162
162
163

10.4

Cost Alternatives Manager

163

10.5

Cost Reports

164

vi

Table of Contents
10.5.1
10.5.2
10.5.3
10.5.4
10.5.5
10.5.6

Element Detailed Cost Report
Project Detailed Cost Report
Project Element Summary Cost Report
Project Summary Cost Report
Pipe Costs Report
Cost Warnings Report

Chapter 11 Presenting your Results

164
165
165
165
165
165

167

11.1

Overview

167

11.2

Element Annotation
11.2.1
Attribute Annotation Dialog
11.2.2
Annotation Properties
11.2.3
The Annotation Wizard

167
167
168
168

11.3

Color Coding
11.3.1
Color Coding Dialog

169
170

11.4

Reporting
11.4.1
Predefined Reports
11.4.2
Element Details Report
11.4.3
Element Results Report
11.4.4
Tabular Reports
11.4.5
Scenario Summary Report
11.4.6
Project Inventory Report
11.4.7
Plan View Report
11.4.8
Calculation / Problem Summary Report

170
170
171
171
172
172
172
172
173

11.5

Graphing
11.5.1
Graph Setup
11.5.2
Graph Window
11.5.3
Plot Window
11.5.4
Graph Options

173
173
174
174
174

11.6

Pie Charts

176

11.7

Profile
11.7.1
11.7.2
11.7.3
11.7.4

176
176
177
179
180

Profile Manager
Profile Templates
Profile Wizard
Profile Window

11.8

Diversion Network
11.8.1
Diversion Network Window
11.8.2
Diversion Network Options
11.8.3
Diversion Network Background Color

183
183
184
184

11.9

Scenario Comparison
11.9.1
Annotation Comparison Wizard
11.9.2
Scenario Comparison Window

184
184
184

11.10 Graphic Annotation
11.10.1 Legend

185
186

11.11 Preview Windows

186

11.12 Status Log

187

Chapter 12 Engineering Libraries
12.1

Engineering Libraries Overview

189
189

Table of Contents

vii

12.2

Engineering Library Manager

189

12.3

Engineering Library Editor

190

12.4

Usage

191

12.5

Extreme Flow Factor Method Library
12.5.1
Extreme Flow Factor Equation Properties
12.5.2
Extreme Flow Factor Table Properties

191
191
192

12.6

Section Size
12.6.1
Section Size Library
12.6.2
Arch Section Size Properties
12.6.3
Box Section Size Properties
12.6.4
Circular Section Size Properties
12.6.5
Ellipse Section Size Properties
12.6.6
Available in Materials

192
192
193
193
194
194
194

12.7

Material Properties
12.7.1
Material Library

195
195

12.8

Minor Loss
12.8.1
Minor Loss Properties

195
195

12.9

Unit Sanitary (Dry Weather) Load
12.9.1
Population-Based Unit Sanitary (Dry Weather) Load Properties
12.9.2
Non-Population-Based Unit Sanitary (Dry Weather) Loads
12.9.3
Area-Based Unit Sanitary (Dry Weather) Loads
12.9.4
Discharge-Based Unit Sanitary (Dry Weather) Loads
12.9.5
Count-Based Unit Sanitary (Dry Weather) Loads

196
196
196
197
197
197

Chapter 13 GIS and Database Connections

199

13.1

Overview

199

13.2

Database Connections
13.2.1
Database Connection Manager
13.2.2
Standard Database Import/Export
13.2.3
Database Connection Editor
13.2.4
ODBC
13.2.5
Sharing Database Connections between Projects
13.2.6
Database Connection Example

201
201
201
203
206
207
208

13.3

Shapefile Connections
13.3.1
Shapefile Connection Manager
13.3.2
Shapefile Connection Editor
13.3.3
Shapefile Link Wizard
13.3.4
Import Shapefile Wizard
13.3.5
Export Shapefile Wizard
13.3.6
Sharing Shapefile Connections between Projects
13.3.7
Shapefile Format
13.3.8
Shapefile Connection Example

208
208
209
210
211
213
214
215
215

Chapter 14 Exchanging Data with
CAD Software and Autodesk Civil Design
14.1

AutoCAD Polyline to Pipe Conversion
14.1.1
Polyline to Pipe Wizard
14.1.2
Polyline to Pipe Wizard - Step 1 (Stand-Alone mode only)
14.1.3
Polyline to Pipe Wizard - Step 2
14.1.4
Polyline to Pipe Wizard - Step 3

217
217
218
218
218
219

viii

Table of Contents
14.1.5
14.1.6
14.1.7
14.1.8
14.1.9
14.1.10

Polyline to Pipe Wizard - Step 4 (for .DXF files that contain blocks)
Polyline to Pipe Wizard - Step 5
Polyline to Pipe Wizard - Step 6
Drawing Preview
Polyline Conversion Problem Dialog
Converting your Drawing in Multiple Passes

219
220
220
220
220
220

14.2

Land Development Desktop - Civil Design Connection
14.2.1
Land Development Desktop Import Wizard
14.2.2
File Import Settings
14.2.3
Runs to Import
14.2.4
Import Structure Mappings
14.2.5
Land Development Desktop Export Wizard
14.2.6
File Export Settings
14.2.7
Runs to Export
14.2.8
Add/Edit Pipe Run
14.2.9
Delete Runs
14.2.10 Initialize Run List
14.2.11 Automatic Element Labeling
14.2.12 Export Structure Mapping

220
220
221
221
221
221
222
222
222
223
223
223
223

14.3

Import/Export of DXF Files
14.3.1
Import a DXF from AutoCAD or MicroStation
14.3.2
Exporting a DXF file
14.3.3
Redefining SewerCAD Blocks in AutoCAD
14.3.4
Advanced DXF Import Techniques

223
223
223
224
224

Chapter 15 Additional Features of the AutoCAD Version

225

15.1

Overview

225

15.2

SewerCAD Custom AutoCAD Entities (AutoCAD Mode)

225

15.3

AutoCAD Environment
15.3.1
AutoCAD Mode Graphical Layout
15.3.2
Toolbars
15.3.3
Drawing Setup
15.3.4
Symbol Visibility
15.3.5
Rebuild Figure Labels

226
226
226
227
227
227

15.4

AutoCAD Project Files
15.4.1
Drawing Synchronization
15.4.2
Saving the Drawing as Drawing*.dwg

227
228
228

15.5

Element Properties
15.5.1
Select Layer
15.5.2
Select Text Style

228
229
229

15.6

Working with Elements
15.6.1
Edit Element
15.6.2
Edit Elements
15.6.3
Deleting Elements
15.6.4
Modifying Elements

229
229
229
229
229

15.7

Working with Elements Using AutoCAD Commands
15.7.1
AutoCAD Commands
15.7.2
Explode Elements
15.7.3
Moving Elements
15.7.4
Moving Element Labels
15.7.5
Snap Menu

230
230
230
230
231
231

15.8

Undo / Redo

231

Table of Contents
15.8.1
15.9

ix
Undo and Redo Operations in AutoCAD

Converting Native AutoCAD Entities to SewerCAD Elements
15.9.1
Converting Native AutoCAD Entities
15.9.2
Layout Pipe Using Entity
15.9.3
Change Entities to Pipes

15.10 Special Considerations
15.10.1 Import SewerCAD
15.10.2 Working with Proxies

Appendix A Frequently Asked Questions

231
231
231
232
232
232
232
233

235

A .1

Overview

235

A .2

How Do I Control Element and Label Sizing?

235

A .3

How Do I Reuse Deleted Element Labels?

235

A .4

How Do I Color Code Elements?

235

A .5

How Do I Remove Color Coding from Labels
Imported from Pre-v3.5 AutoCAD Files?

236

A .6

How Do I Do a Profile Plot?

236

A .7

How Do I Change Units in a Column?

236

A .8

How Do I Access the Haestad Methods Knowledge Base?

237

A .9

How do I Model an Inverted Siphon (Depressed Sewer)?

237

Appendix B SewerCAD Theory
B .1

Overview

B .2

Loading
B.2.1
B.2.2
B.2.3
B.2.4

239
239

Common Load Types
Sanitary (Dry Weather) Loading
Wet Weather Loading
Known Loading

239
240
241
242
243

B .3

Gravity Pipe Hydraulics
B.3.1
Basic Concepts
B.3.2
Hydraulics and Energy Grades
B.3.3
Friction Loss Methods
B.3.4
Flow Regime
B.3.5
Gradually Varied Flow Analysis
B.3.6
Energy Balance
B.3.7
Mixed Flow Profiles
B.3.8
Backwater Analysis
B.3.9
Frontwater Analysis
B.3.10
Pipe Average Velocity
B.3.11
Capacity Analysis (Approximate Profiles)

244
244
244
245
249
250
252
253
254
254
255
256

B .4

Junction Headlosses and Minor Losses
B.4.1
Junction Headlosses
B.4.2
Minor Losses

258
258
266

B .5

Pumping Stations and Pressure Sewers
B.5.1
Pump Theory
B.5.2
Pump Type
B.5.3
Conservation of Mass and Energy
B.5.4
The Gradient Algorithm
B.5.5
Derivation of the Gradient Algorithm

267
267
269
270
270
271

x

Table of Contents
B.5.6

The Linear System Equation Solver

273

B .6

Extended Period Simulations
B.6.1
Extended Period Simulations Overview
B.6.2
Routing Overview
B.6.3
Convex Routing
B.6.4
Weighted Translation Routing
B.6.5
Hydrologic and Hydraulic Time Steps

274
274
274
274
275
276

B .7

Transitioning between Gravity and Pressure Networks
B.7.1
Overview
B.7.2
Identifying Gravity Pipes and Force Mains
B.7.3
Direction of Flow in Gravity and Pressure Systems
B.7.4
Transitioning From Gravity Pipes to Force Mains
B.7.5
Transitioning From Force Mains to Gravity Elements

276
276
276
276
277
277

B .8

Constraint Based Automatic Design
B.8.1
Gravity Pipes and Structures Design
B.8.2
Part Full Design
B.8.3
Allow Multiple Sections
B.8.4
Limit Section Size
B.8.5
Pipe Matching
B.8.6
Offset Matching
B.8.7
Drop Structures
B.8.8
Structure Sump Elevations
B.8.9
Design Priorities
B.8.10
Automatic Design with Hydrograph and Pattern Loads
B.8.11
Constraint Based Warning Messages

280
280
281
281
282
282
282
283
283
283
285
286

B .9

Special Considerations
B.9.1
Energy Discontinuity
B.9.2
Structure Energy Grade
B.9.3
Design Considerations
B.9.4
Reporting Flow Attributes

286
286
286
287
287

B .10 Engineer's Reference
B.10.1
Default Kinematic Viscosity
B.10.2
Headloss Coefficients for Junctions
B.10.3
Roughness Values - Manning's Equation
B.10.4
Roughness Values - Kutter’s Equation
B.10.5
Roughness Values - Darcy-Weisbach Equation (Colebrook-White)
B.10.6
Roughness Values - Hazen-Williams Formula
B.10.7
Typical Roughness Values for Pressure Pipes

Appendix C Importing Loading Data

287
288
289
290
290
291
292
293

295

C .1

Importing Loading Data Overview

295

C .2

Import Loading Data Dialog

295

C .3

Loading Data Text File Format
C.3.1
ASCII Loading Data Format
C.3.2
Constant Increment Patterns Section
C.3.3
Variable Increment Patterns Section
C.3.4
Sanitary Pattern Loads Section
C.3.5
Wet Pattern Loads Section
C.3.6
Constant Increment Hydrographs Section
C.3.7
Variable Increment Hydrographs Section
C.3.8
Sanitary Hydrograph Loads Section
C.3.9
Wet Hydrograph Loads Section

296
296
296
296
297
297
298
298
299
299

Table of Contents
C.3.10
C.3.11
C.3.12

xi
Sanitary Unit Loads Section
Options Section
ASCII Loading Data Example

Appendix D Scenario Management Reference Guide

300
300
301

303

D .1

Overview

303

D .2

About this Guide

303

D .3

Before Haestad Methods: Distributed Scenarios

304

D .4

With Haestad Methods: Self-Contained Scenarios

305

D .5

The Scenario Cycle

305

D .6

Scenario Anatomy: Attributes and Alternatives

306

D .7

A Familiar Parallel

306

D .8

Scenario Behavior: Inheritance

307

D .9

Overriding Inheritance

307

D .10 Dynamic Inheritance

308

D .11 When are values local, and when are they inherited?

308

D .12 Minimizing Effort through Attribute Inheritance

308

D .13 Minimizing Effort through Scenario Inheritance

309

D .14 A Water Distribution Example

310

D .15 Building the Model (Average Day Conditions)

310

D .16 Analyzing Different Demands (Maximum Day Conditions)

311

D .17 Another Set of Demands (Peak Hour Conditions)

311

D .18 Correcting an Error

312

D .19 Analyzing Improvement Suggestions

312

D .20 Finalizing the Project

313

D .21 Summary

313

D .22 Conclusion

314

Appendix E Haestad Methods Software

315

E .1

Overview

315

E .2

WaterCAD

315

E .3

SewerCAD

315

E .4

StormCAD

316

E .5

PondPack

316

E .6

CulvertMaster

316

E .7

FlowMaster

316

xii

Table of Contents

Glossary

317

References

333

Index

335

Preface

xiii

Preface
Welcome to SewerCAD
Thank you for purchasing SewerCAD. At Haestad Methods, we pride ourselves in providing the very best
engineering software available. Our goal is to make software that is easy to install and use, yet so powerful
and intuitive that it anticipates your needs without getting in your way.
SewerCAD is a feature-rich program with extensive on-line documentation that is able to provide a level of
instruction appropriate to your needs. Do not be fooled by the existence of this user’s guide. You do not
need to read anything to get started!
When you first use the program, SewerCAD’s intuitive interface and interactive dialogs will guide you. If
you need more information, go to our on-line help by simply pressing the F1 key anywhere in the program.
Help text regarding the area of the program in which you are working will be displayed.
We are betting that you will be able to use our product right out of the package. If you know how to run
Setup within Windows, then go ahead and get right to work - install SewerCAD, and enjoy!

Notes

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Chapter 1
Orientation
1.1 What is SewerCAD?
SewerCAD is an extremely powerful program for the design and analysis of gravity flow and pressure flow
through pipe networks and pumping stations. The program can be run in AutoCAD mode, giving you all
the power of AutoCAD’s capabilities, or in Stand-Alone mode utilizing our own graphical interface.
SewerCAD allows you to construct a graphical representation of a pipe network containing information
such as pipe data, pump data, loading, and infiltration. You have a choice of conveyance elements
including circular pipes, arches, boxes and more.
The gravity network is calculated using the built-in numerical model, which utilizes both the direct step and
standard step gradually varied flow methods. Flow calculations are valid for both surcharged and varied
flow situations, including hydraulic jumps, backwater, and drawdown curves. You also have the flexibility
to mix gravity and pressure components freely, building your systems in parallel or in series as they exist in
the field. Pressure elements can be controlled based on system hydraulics, turning pumps on and off due to
changes in flows and pressures.
SewerCAD’s flexible reporting feature allows you to customize and print the model results in both a report
format and as a graphical plot.

1.2 When to Use SewerCAD?
SewerCAD is so flexible you can use it for all phases of your project, from the feasibility report to the final
design drawings and analysis of existing networks. During the feasibility phase, you can use SewerCAD to
create several different system layouts with an AutoCAD or MicroStation drawing as the background, or
within AutoCAD itself. For the final design, you can complete detailed drawings with notes that can be
used to develop the construction plans. In summary, you can use SewerCAD to:


Design multiple sanitary sewer systems.



Analyze various design scenarios for sanitary sewer systems.



Import and export AutoCAD and MicroStation .DXF files.



Generate professional-looking reports for clients.



Generate plan and profile plots of a network.

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1.3 What's New in SewerCAD?
What’s New in SewerCAD 5.0


Extended Period Simulations - Run time-based simulations routing hydrographs, fixed and pattern
loads through complex sanitary networks containing both gravity and pressure elements.



Element Graphing and Tables - Generate graphs and tables comparing information for different
hydraulic elements as well as different scenarios over time.



Diurnal Loading Patterns - Apply diurnal patterns to fixed loads or to unit sanitary loads.



Loading Data Import - Import multiple unit sanitary loads, wet weather loads, hydrographs and
diurnal patterns from a formatted ASCII text file.



Panning - Scroll easily through a SewerCAD drawing using your mouse with new panning support.



Profile Customization - Create profiles with custom annotations, layer properties, and direction in
order to mimic all design drawing and master plan requirements.



Persistent Profiles - Store unlimited different customized profile views using the Profiles Manager
within the same network model.



Profile Templates - Create templates that can be applied to new profiles. The templates will then
establish the annotations and text properties for the new profile, instead of having to reestablish all the
information.



Editable Quick View – Edit data efficiently through the Quick View window without having to open
an element’s dialog.



Wet Well Alarm Levels - Trigger a warning message or a change in color coding when the water
surface elevation in a wet well during an analysis goes above a user-specified alarm level.



Improved Results Reporting - View calculation results in an intuitive directory structure. Warning
and error messages are organized in a single printable table.



Animated Displays - Animate the plan and profile views separately or at the same time to serve as an
ideal tool for presentations and output analysis.



Quick Attribute Selector - Select attributes for annotations, color coding, tables, and database / GIS
connections from logically organized categories.



Mouse Wheel Support - Pan and zoom using the mouse wheel.



Microsoft Office XP Support - Take advantage of the capabilities of Microsoft Excel XP and Access
XP for cut-copy-and-paste, as well as database integration.



Windows XP Support - Load the current version of SewerCAD on Windows 95, Windows 98, NT
4.0, Me, Windows 2000, and Windows XP.

What’s New in SewerCAD 4.1.1


Diversions and Overflows - Model CSO and SSO’s, flow splits, basement flooding, or any other
situation where a portion of flow needs to be removed from a gravity system.



Sticky Pipe Inverts - Attach gravity pipe inverts to the sump of the adjacent element or specify the
pipe inverts independently. If you select the "sticky pipe invert" mode, pipe inverts will move as you
adjust the element sump elevation.



Minimum Structure Headloss - Specify a global minimum structure headloss as required by many
regulatory agencies.

Orientation


3

Generic Headloss Method - Provides the flexibility needed to accommodate any headloss
methodology that relies on both upstream and downstream velocity heads.

What’s New in SewerCAD 4.1


Network Licensing - Purchase a multi-seat license. With the purchase of the AutoCAD version of
SewerCAD, your engineers and technicians can individually use SewerCAD in either Stand-Alone
mode or AutoCAD mode and share project files.



Performance Optimization - Experience a 150% performance increase in Calculation Engine, 200%
increase in Model Validation, 100% increase in Graphical Editor, and 200% performance increase in
opening and saving files.



Persistent Sorts and Filters - Maintain user-defined sorts and filters each time a table is opened.



Appearance of Drawing Environment - Enjoy total control over background and foreground colors
in the graphical editor.



Aerial View - Access this separate window to facilitate zooming, panning, and locating a small
viewing area in the main window.



Cost Estimating - Perform detailed cost estimates using an integrated cost analysis modeling
subsystem.



Extensive Documentation - Access our extensive Internet-based support database, called the
KnowledgeBase, through our ClientCare Program.



Technical Support - Subscribe to one of our ClientCare packages and access technical support
seven days a week.

1.4 Installation, Upgrades and Updates
1.4.1

Minimum System Requirements
Below are the minimum and recommended system requirements for running SewerCAD with acceptable
performance. Some of the requirements for AutoCAD Mode, such as RAM, are fairly high due to
AutoCAD and operating system demands, not SewerCAD itself.
Stand-Alone Mode:
Processor:

Pentium-166

RAM:

32 Megabytes

Hard Disk:

25 Megabytes of free storage space, plus room for data files

Display:

800 x 600 resolution, 256 colors

AutoCAD Mode:
Processor:

Pentium-166

RAM:

64 Megabytes

Hard Disk:

25 Megabytes of free storage space, plus room for data files

Display:

800 x 600 resolution, 256 colors

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Recommended:
While Haestad Methods' software will perform adequately given the minimum system requirements,
performance will only improve with a faster system. Our products are designed to perform at optimal
levels with a fast CPU and ample amounts of RAM and free disk space. We highly recommend running
our software on the best system possible to maximize its potential. We understand that an engineer's time
is a valuable commodity, and we have designed our software to help make the most of that time.

1.4.2

Installing Haestad Methods' Products
For Windows 95, Windows 98, Windows NT 4.0, Windows 2000, Windows Me, and Windows XP follow
these six easy steps, for installing a single user license copy of the program:
1.

If you have not done so, turn on your computer.

2.

Place the diskette labeled Disk 1 in the floppy disk drive (commonly the a: or b: drive).

3.

Place the CD in your CD-ROM drive (commonly the d: or e: drive).

4.

If the Autorun feature of the operating system is enabled, setup will begin automatically. Proceed
to step six.

5.

If Autorun is disabled, click the Start button on the task bar, select Run from the menu, and type
d:\setup (use the actual drive letter of the CD-ROM drive if it is not the d: drive), and then click
OK.

6.

Follow the instructions of the Setup Wizard.

If you own a network license version of the software, please refer to the Network Licensing
section. If you still have questions, consult the KnowledgeBase on our web site www.haestad.com
or contact Haestad Methods technical support.

1.4.3

Uninstalling Haestad Methods' Products
Haestad Methods' products come with an uninstall option. After a single user license copy of a Haestad
Methods' product is installed onto a computer, it must be uninstalled before a new installation can occur.
To uninstall the program:
On the Windows Start Bar, click Start / Programs / Haestad Methods / Product Name / Uninstall
Product Name. The original floppy disk labeled Disk 1 that came with the product must be in the floppy
drive at the time you uninstall.

1.4.4

Troubleshooting Setup or Uninstall
Because of the multi-tasking capabilities of Windows 95, 98, NT, 2000, Me, and XP you may have
applications running in the background that make it difficult for the setup routines to determine the
configuration of your current system. If you have difficulties during the install (setup) or uninstall process,
please try these steps before contacting our technical support staff:
1.

Restart your machine.

2.

Verify that there are no other programs running. You can see applications currently in use by
pressing Ctrl-Alt-Del in Windows 95, 98, Me, XP, or 2000, or Ctrl-Shift-Esc in Windows NT.
Exit any applications that are running.

3. Run setup or uninstall again without running any other program first.
If these steps fail to successfully install or uninstall the product, contact our support staff immediately.

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1.4.5

5

Software Registration
During the installation of the program, a dialog will appear asking you to register the software. Please note
the label with your registration information is on the inside back cover of the manual.
Although this software is not copy protected, registration is required to unlock the software capabilities for
the hydraulic features that you have licensed. All registration information must be entered into the
Registration dialog exactly as it appears on the label.


Company



City



State/Country



Product ID

• Registration Number
After you have registered the software, you can check your current registration status by opening the
registration dialog in the software itself.
To open the Registration dialog:
1.

Select Help / About from the pull-down menus.

2. Click the Registration button in the About dialog.
The current registration status (number of licenses, expiration date, feature level, etc) will be displayed.
Use the Print button to print a copy of the information shown in the Registration Form dialog.
Use the Copy button to place the registration information in the Windows Clipboard so that you can paste
it into another Windows application.
If you own a network license version of the software, please refer to the Network Licensing
section. If you still have questions, consult the KnowledgeBase on our web site www.haestad.com
or contact Haestad Methods technical support.

1.4.6

Upgrades
When you click the Registration button on the Help / About Product Name … dialog, the current
registration status (number of licenses, expiration date, feature level, etc) is displayed. To upgrade to more
pipes or inlets, higher feature levels, or additional licenses, contact our sales team today and request
information on our ClientCare Program. We will provide the information you need to get up and running
in no time!

1.4.7

Globe Button
Haestad Methods makes it easy to stay up-to-date with the latest advances in our software. Software
maintenance releases can be downloaded from the Haestad Methods web site quickly and easily if you are a
subscriber to our ClientCare Program. Just click the Globe icon on the tool palette to launch your preferred
web browser and open the Haestad Methods’ Program Update web site. The web site will automatically
check to see if your installed version is the latest available. If it is not, it will provide you with the
opportunity to download the correct upgrade to bring it up-to-date.
The ClientCare Program also gives you access to our extensive KnowledgeBase for answers to Frequently
Asked Questions (FAQ). Contact our sales team for more information on our ClientCare Program.

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Use the Globe button to keep your investment current.

1.4.8

Network Licensing
Network versions of this product are available. If you purchased a network version, your program will run
at any workstation located on your network if a floating license key is available for use. Floating licenses
allow one or more concurrent users of a particular application to access and use the full capabilities of the
software if the number of concurrent licenses does not exceed the number allowed under the terms of the
license sale. Once the number of concurrent users exceeds the licensed number, new application sessions
will run in a limited demo mode.
Network licensing is implemented using Rainbow Industries SentinelLMTM license manager.
Administrators should refer to the SentinelLMTM System Administrators Guide for details on implementing
network licensing at your location.

Registering Network Programs
During the installation of the network deployment folder, a dialog will appear asking you to register the
software. The label with your registration information is on the inside back cover of the manual. This
registration data is required to enable the software capabilities for the hydraulic network size and features
that you have licensed. All registration information must be entered into the Registration dialog exactly as
it appears on the label.


Company



City



State/Country



Product ID

• Registration Number
After you have registered the software, you can view the current registration and floating license usage
status at any of the workstations that has the product software installed on it.
To open the Registration dialog:
1.

Select Help / About… from the pull-down menus.

2. Click the Registration button.
The current registration status (number of floating licenses, expiration date, feature level, etc) will be
displayed. If all available floating licenses are in current use, the software will run in demo mode.
Network administrators may activate network licenses and upgrade the features served by their floating
licenses by invoking the Request License option, which is activated using the Registration button on this
dialog.
Use the Print button to print a copy of the information shown.
Use the Copy button to export the registration information to the Windows Clipboard so that you can paste
it into other Windows applications.

Orientation

7

Requesting Permanent Network License
System administrators who are responsible for managing network license versions of Haestad Methods'
software must activate their organization’s floating licenses by obtaining a permanent license file from
Haestad Methods. This may be done using the Request License button on the Registration dialog. This
button will only be available for users who have purchased the network-licensing feature.
Haestad Methods uses SentinelLM License Manager software from Rainbow Technologies to
manage network licensing for this application. For more information concerning the
administration of the Haestad Methods floating network licensing, please refer to the Sentinel
Software System Administrator’s Guide online documentation installed with your network
license server software.
To acquire a network license file, the administrator must first generate the network locking codes for the
computer that will be acting as the network license server. To get you license server locking code, use the
SentinelLM echoid utility. This is installed with the license server software onto the computer acting as the
network license host for this application.
The echoid utility must be run from the same computer that will act as the license server host for
this particular Haestad Methods application.
Write down the values for the locking codes that are posted in the echoid utility’s message box. Be certain
to record these values accurately, as they will be used by Haestad Methods to generate a custom license file
keyed to the specific license server’s hardware signature. Once issued, a license key-code may not be
installed on another machine. You will not be able to transport the license server to another network
machine without obtaining new lock codes.
With echoid values in hand, start the Haestad Methods product application on any workstation located on
the network served by the license manager. You can even install and run the Haestad Methods application
from the same computer that will be acting as the license server host computer.
Select Help / About… from the pull-down menus to open the Registration dialog. Open the Request
License Key dialog using the Request License button. Fill out the form, then either email or fax the
completed form to Haestad Methods using the Submit Request button.

Installation Guide for Network License Versions
To set up a Haestad Methods’ software product for operation as a network licensed version:
1.

Place the diskette labeled Disk 1 in the floppy disk drive (commonly the a: or b: drive).

2.

Place the CD in your CD-ROM drive (commonly the d: or e: drive).

3.

If the Autorun feature of the operating system is enabled, setup will begin automatically. Proceed
to step 5.

4.

If Autorun is disabled, click the Start button on the task bar, select Run from the menu, and type
d:\setup (use the actual drive letter of the CD-ROM drive if it is not the d: drive). Click OK.

5.

To perform the following steps, you must have full administrator privileges for the target
network-based installation folders. Follow the instructions of the Setup Wizard, which will
guide you through the installation of two components:


Network deployment folder - A directory installed on a network node that is available from
all client workstations on which the license product will be installed. Users of the floating
licenses will invoke the network-based installation utility setup.exe, which will install and
configure the application to each client workstation.

8

Orientation


6.

Network License Manager and Utilities - The license manager service executable file that
will automatically monitor availability and distribute network floating licenses to client
applications as they are started up across the license hosting LAN. The license manager may
be installed on any shared node in the network, but is generally located on a network server
machine.

Start the license server using the appropriate procedure for the host machine’s operating system:


Windows NT/2000 - Use the loadls utility via the Service Loader menu option to install the
license server. The license manager runs as a service and can be manually controlled via the
Windows NT / 2000 Control Panel / Services group.



Windows 95/98/ME - To enable automatic license server startup, use Windows Explorer to
add the license server program, Lserv9x.exe, to the Windows 95/98 system StartUp folder.
Manually start the license server by running the lserv9x via the License Server menu option.

7.

Announce the availability of the product via email. Instruct interested users to install the product
the using the Start / Run… menu command and browsing to the network deployment folder
installed in step 5 to run setup.exe. The license server ships with special 30-day licenses that
will allow users to begin using the application immediately.

8.

Obtain a permanent license file for the application. A permanent license file must be obtained
from Haestad Methods within 30 days of receipt of the product package. Request a permanent
license file by following these steps:

9.



At the host computer on which the license server will run, use the echoid utility via the
Locking Codes menu option to determine the locking codes that will be used to generate
license keys for your network. The license key file will be configured specifically for the
license server machine installation. Write these locking codes down.



Start the Haestad Methods' product application at any workstation where the product has been
installed. The product can even be installed directly on the computer acting as the license
server.



Select Help / About … from the pull-down menus and click the Registration button. Use the
Request License button at the bottom of the Registration dialog and fill out the License Key
Request form with the system administrator contact and host server locking code information.
Be certain to accurately record the locking codes obtained during the previous step since
inaccurate information will result in the generation of unusable license files.



Click the Submit Request… button. Following the instructions in the form, e-mail or fax the
form to Haestad Methods. The activation request will be processed, and a license file will be
generated and e-mailed to the system administrator making the request.

Use the lslic utility located in the AdminTools directory to modify the permanent license file
managed by the network license server. After the license key file requested above is received via
e-mail from Haestad Methods, save the file attachment to a computer folder on any computer
resident on the network serviced by the running license server. For future convenience, safety,
and ease-of-support, it is recommended that the license file be saved in the license manager tools
directory, AdminTools. This utility must be run from the operating system prompt. Enter
lslic -F <filename>, where <filename> is the name of the license file attachment
emailed by Haestad Methods and saved to the hard-drive. This step will install the new license
key into the license file, lservrc, located on the same computer and in the same directory that the
license server resides.
Once these steps are completed, floating licenses will be available to concurrent users via the network.
Should the number of users exceed the number of license keys available, the unlicensed client sessions will
continue to run in demo mode.

Orientation

9

Network Deployment Folder
Interested users may install the complete product via the network deployment folder using the Windows
Start / Run command. Browse to the deployment directory, and run setup.exe to install the program to a
client workstation.

1.5 Learning SewerCAD
1.5.1

SewerCAD Documentation
SewerCAD’s on-line documentation delivers extensive detail and convenient assistance. Simply click the
Help button, press the F1 key, or right-click anywhere in the program to access context-sensitive help.
The SewerCAD User’s Guide is provided to you as a means to read and learn about SewerCAD while you
are away from your computer. The topics you find in the User’s Guide will also be found in the on-line
help.
SewerCAD also contains on-line tutorials, lessons, and sample files to get you familiar with the features
and capabilities of SewerCAD. The tutorials can be accessed by clicking Help / Tutorials from the pulldown menus. The lessons can be found in the printed documentation, as well as in the on-line Help. The
sample files are located in your Haestad\SWRC\Sample directory.

1.5.2

How to Use Help
All of our products feature extensive context-sensitive help. There are several ways to obtain help on
topics:


Select Help from the pull-down menu.



To get help for the window in which you are working, press the F1 key or click the Help button.

• To get help for a specific item, right-click the desired item and select Help from the pop-up menu.
To navigate within Help:


When you click text that is underlined, Help “jumps” to the related topic or definition. If the text is
dashed underlined, the text will appear in a pop-up window.



To return to the previous topic, click the Back button at the top of the Help window.



To print a Help topic, click the Print button at the top of the Help window.
To make the Help window stay on top of other windows, select Options / Keep On Top / On Top
from the pull-down menu in the main Help window.

1.5.3

How Do I?
How Do I is an easily referenced topic in SewerCAD’s on-line documentation. It is a listing of commonly
asked questions about SewerCAD. Just follow these steps to find your way to How Do I:
1.

Click Help / How Do I from the pull-down menu

2.

The listing of How Do I topics will appear. Just click the topic of your choice for a detailed
explanation.

3.

To return to the listing of How Do I questions, click the Back button.

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Help
Provides context sensitive help for the current window.

1.5.4

Glossary
The glossary contains many terms used throughout the application and the on-line Help.
To use the Glossary:

1.5.5

1.

Click Help / Contents to open the main Help window.

2.

Click the Contents tab, and then double-click the Glossary book.

3.

Click the Glossary page, and the Glossary topic will appear.

4.

Click the first letter of the word for which you are looking for more information.

5.

Click the desired term, and a pop-up box will appear with a definition of the selected word.

Tutorials
Tutorials provide a quick introduction to various features of the program. To access tutorials, click Help /
Tutorials from the pull-down menus. Run a tutorial by selecting one of the entries in the list and clicking
the OK button.
End a tutorial at any time by either pressing the Esc key (in Stand-Alone mode), or by clicking the Close
button in the upper right-hand corner of any tutorial dialog. If you need further information, access our online help by pressing the F1 key.

1.5.6

Sample Projects
To explore one of the sample projects provided to demonstrate this software’s capabilities:
1.

Select File / Open from the pull-down menus to access the Open Project File dialog.

2.

Choose Sample.swr (or Sample.dwg, if using AutoCAD mode) from the Sample directory, and
click Open.
These are working network models, so you can explore the system and see how different elements are
modeled. First, calculate the system by using the GO button on the main toolbar. Then use Quick View,
Graphs, Profiles, Tabular views, Detailed Reports, and Color Coding to see how the system behaves. To
get the best introduction to a new feature, try running some of the tutorials.

1.5.7

Haestad Methods Workshops and Certification
Haestad Methods offers a variety of workshops dealing with topics ranging from urban stormwater
management to water distribution modeling, alternating theory, modeling insights and hands-on practice
with the software. These workshops are held at various locations throughout the world, and include
discounted pricing when purchasing Haestad Methods software.
For more information on our workshops (such as instructors, schedules, pricing, and locations), please
contact our sales department, or visit our web site at www.haestad.com for current workshop schedules and
locations. We will be glad to answer any questions you may have regarding the workshops and our other
products and services.

Orientation

11

1.6 Contacting Haestad Methods
1.6.1

Sales
Haestad Methods’ professional staff is ready to answer your questions. Please contact your sales
representative for any questions regarding Haestad Methods’ latest products and prices.
Phone: +1-203-755-1666
Fax:

+1-203-597-1488

e-mail: [email protected]

1.6.2

Technical Support
We hope that everything runs smoothly and you never have a need for our technical support staff.
However, if you do need support our highly skilled staff offers their services seven days a week, and may
be contacted by phone, fax, and the Internet. For information on the various levels of support that we offer,
contact our sales team today and request information on our ClientCare Program.
When calling for support, in order to assist our technicians in troubleshooting your problem, please
be in front of your computer and have the following information available:


Operating system your computer is running (Windows 95, Windows 98, Windows NT, Windows Me,
Windows 2000, or Windows XP)



Name and version number of the Haestad Methods software you are calling about



Version of AutoCAD you are running (if applicable)



Any error messages or other information that was generated

• A note of exactly what you were doing when you encountered the problem
When e-mailing or faxing for support, please provide the following additional details to enable us to
provide a timely and accurate response:


Company name, address, and phone number



A detailed explanation of your concerns

• The Haestad.log and Error.log files located in the product directory (e.g. Haestad\SewerCAD).
Hours:
Monday - Friday:

9:00 AM to 8:00 PM EST

Saturday and Sunday:

9:00 AM to 5:00 PM EST

You can contact our technical support team at:
Phone: +1-203-755-1666
Fax:

+1-203-597-1488

e-mail: [email protected]

12

1.6.3

Orientation

Your Suggestions Count
At Haestad Methods, we strive to continually provide you with sophisticated software and documentation.
We are very interested in hearing your suggestions for improving our products, our on-line Help system,
and our printed manuals. Your feedback will guide us in developing products that will make you more
productive.
Please let us hear from you!

1.6.4

How to Contact Us
Phone: +1-203-755-1666
Fax:

+1-203-597-1488

e-mail: [email protected]
[email protected]
[email protected]
Internet: http://www.haestad.com
Mail:

Haestad Methods
37 Brookside Road
Waterbury, CT 06708-1499
USA

SewerCAD Main Window

13

Chapter 2
SewerCAD Main Window
2.1 Overview
If you are already familiar with standard Windows interfaces, you will find SewerCAD to be intuitive and
comfortable. Even if you are not accustomed to Windows standards, just a few minutes of exploring
SewerCAD should be enough to acquaint you with the flexibility and power that this program offers.
In this chapter, we will examine the program's main window, menus, and toolbars. Additional tools for
layout, annotating and editing are described in the chapter "Layout and Editing Tools." After reading this
chapter, you should be able to interact with SewerCAD in a quick and efficient manner.

2.2 Main Window Components
2.2.1

Stand-Alone Mode, AutoCAD Mode
Both the Stand-Alone graphical editor and the AutoCAD interface perform modeling activity through the
SewerCAD model server.
This use of a common central model enables both modes to perform the same functions with the same
behaviors, so things like graphical layout and model management are virtually identical between the two
modes.
One advantage of Stand-Alone mode is that your interaction is more streamlined and dynamic by virtue of
the fact that the editing environment is a dedicated network editor. Also, since AutoCAD is not needed to
run in Stand-Alone mode, less system resources and memory are used.
A significant advantage of the AutoCAD mode is that you can create and model your network directly
within your primary drafting environment. This gives you access to all of AutoCAD’s powerful drafting
and presentation tools, while still enabling you to perform SewerCAD modeling tasks like editing, solving,
and data management. This relationship between SewerCAD and AutoCAD enables extremely detailed and
accurate mapping of model features, and provides the full array of output and presentation features
available in AutoCAD. This facility provides the most flexibility and the highest degree of compatibility
with other CAD-based applications and drawing data maintained at your organization.
AutoCAD mode is an available feature level. Contact us to upgrade your SewerCAD StandAlone version to include the AutoCAD mode feature level.

2.2.2

SewerCAD Main Windows
Both the SewerCAD Stand-Alone interface and the AutoCAD interface have many components common to
Windows based programs. The following figures illustrate some of the important areas that make up the
SewerCAD Stand-Alone, AutoCAD R14 and AutoCAD 2000 windows, respectively.

14

SewerCAD Main Window
SewerCAD Stand-Alone Interface

SewerCAD AutoCAD R14 Interface

SewerCAD Main Window

15
SewerCAD AutoCAD 2000 Interface

Notice that many of the window components, such as menus and toolbars, are very similar for the StandAlone editor and AutoCAD. Other features, such as the command line, are only available in AutoCAD.
For more information regarding the various functions and behaviors of AutoCAD, please refer to your
AutoCAD documentation.

2.2.3

Drawing Pane
The drawing pane is the center of SewerCAD’s graphical activity, where the sanitary sewer network
elements are displayed. It is the main interactive area for creating elements, editing data, and even
displaying results.
In Stand-Alone mode, the drawing pane can also display a single .DXF background image. This
background can be helpful for aligning and positioning elements, as well as adding additional drafting
elements for plotting plan views.
In AutoCAD, the drawing pane is where all graphical elements, not just SewerCAD entities, are displayed
and manipulated. Lines, arcs, text, and many other drafting elements can be created and modified within
the drawing pane.

2.2.4

Status Pane
The status pane is located along the bottom of the main application window and provides useful
information about application settings, the current user activity, file save status, etc.
When you position the mouse pointer over a toolbar button or menu item, the status pane will
display a descriptive message. Leave the mouse over a section of the status pane to display an
informative popup tip.

16

2.2.5

SewerCAD Main Window

Menus, Toolbars, and Shortcut Keys
Anyone who has ever watched someone else use a computer should realize that not all people use
computers in the same way. Some prefer to primarily use the mouse, some the keyboard, and others use a
mixture of both.
For this reason, Haestad Methods’ programs provide access to the most common features through several
means, including:


Pull-Down Menus



Toolbars



Shortcut Keys



Command Line (AutoCAD Only)

Pull-down Menus
As with any Windows-based program, the menu system provides easy access to many features. Items can
be accessed by clicking the desired menu text, or by pressing the Alt key to activate the menus and then
pressing the key for the underlined letter of the menu item you wish to access.
For example, to open an existing file you can use the mouse to select File / Open, or you can press the Alt
and F keys (Alt + F), then O on the keyboard.

Toolbars
Toolbar buttons offer one-click access to some of the most commonly used features, giving you a quicker
way to perform the most frequent operations.
For example, to open an existing file (the equivalent of selecting File / Open from the pull-down menu),
simply click the File Open tool.

Shortcut Keys
Shortcut keys are the keyboard equivalent of toolbars. Key combinations - usually a simultaneous
application of the Ctrl (Control) key and a letter key - can provide instant access to common features. If a
shortcut is available for a menu item, it will be indicated in the menu itself.
For example, to open an existing file (the equivalent of selecting File / Open from the pull-down menus)
you can press the Ctrl and O keys (Ctrl + O) at the same time.

2.2.6

Command Line
The command line is a special area that is not available in Stand-Alone mode. In AutoCAD mode, this area
enables you to type commands directly, rather than using the menus, toolbars, or shortcut keys.
For example, to open an existing AutoCAD file (the equivalent of selecting File / Open from the pull-down
menus) you can simply type the command OPEN at the AutoCAD command line.

SewerCAD Main Window

17

Many of AutoCAD’s commands are easy to enter at the command line, including accessing drafting tools
(like LINE and CIRCLE) and editing tools (like MOVE and ERASE). Modeling elements can also be
manipulated through the AutoCAD command line, just as they can be manipulated via the menus or
toolbars.
For more information on the AutoCAD command line, please see the AutoCAD documentation.

2.3 SewerCAD Menus
2.3.1

Pull-down Menus
Although the toolbars and shortcut keys provide quick and easy access to commonly used features, the pulldown menu system provides much more comprehensive access to SewerCAD’s properties and behaviors.
Since toolbar buttons and shortcut keys do not exist for all of these features, the menus are a logical choice
for exploring all areas of SewerCAD. This section will introduce you to many of SewerCAD’s features
and show you how you can access these features, including any toolbar buttons and shortcut keys that are
available.
Commands are grouped under several menus, which consist of the following selections:

2.3.2



File



Edit



Analysis



View



Tools



Report



Draw (in AutoCAD mode only)



Help

File Menu
The File menu contains many of the items dealing with project management. It provides features to create,
read, write, and print project files, as well as features for sharing data with databases and geographical
information systems.


New - Create a new project. When you choose this item, a dialog will appear so that you can enter a
drive, directory, and filename for your new project file. The Project Setup Wizard will then help you
set up your new project.
Toolbar Button:
Shortcut Key: Ctrl + N



Open - Load an existing project file from disk. When you select this item, a dialog will appear so you
can choose the name and location of the project you want to open.
Toolbar Button:
Shortcut Key: Ctrl + O

18


SewerCAD Main Window

Save - Save the current project file to disk. While saving the project file, the status pane will display a
message to show you the progress of the save command.
Toolbar Button:
Shortcut Key:

Ctrl + S



Save As - Save the current project to disk under a different filename. When you use this command, a
dialog will appear prompting you to enter the drive, directory, and a new file name for your project.



Project Summary - Access the Project Summary information, such as the project title and the project
engineer.



Import / Database - Import data from a Microsoft Access database (.mdb) using one of the default
database import connections included with the product.



Import / Shapefile - Build network elements from ESRI Shapefiles. This command will start the
Shapefile Wizard, which will help you bring the GIS elements and their associated data into your
project.



Import / Polyline to Pipe (Stand-Alone Mode Only) - Build network elements from a .DXF file. This
command will start the Polyline to Pipe Wizard, which will help you convert polyline data
representing geographical data into your project as pipes and nodes. A similar command called
‘Change Entities to Pipes’ is available in the AutoCAD version.



Import / Land Development Desktop - Build SewerCAD network elements from Land Development
Desktop Pipes data. This command will start the Land Development Desktop Import Wizard,
which will help you bring the data contained in the Pipes module into your SewerCAD project.



Import / Loading Data - Import hydrograph and temporal pattern data from an ASCII text file.



Import / DXF Background (Stand-Alone Mode Only) - Bring in a single .DXF drawing file into your
project as a background map. This command will open a dialog that prompts you to select the name
and location of the desired .DXF file.



Import / SewerCAD (AutoCAD Mode Only) - Import a SewerCAD (.swr) file into SewerCAD in
AutoCAD mode.



Export / Database - Export data to a new Microsoft Access database (.mdb) using one of the default
database export connections included with the product.



Export / Shapefile - Export your project to ESRI Shapefiles for use with GIS applications. This
command will start the Shapefile Wizard, which will help you create Shapefiles with the desired
project elements and their associated data.



Export / Land Development Desktop - Export SewerCAD network elements into a Land
Development Desktop project. This command will start the Land Development Desktop Export
Wizard, which will help you bring the data contained in your SewerCAD project into the Land
Development Desktop through the Pipes module.



Export / DXF File - Export the entire network drawing to a .DXF file, which can be read by all
popular CAD programs. This command will open a dialog prompting you to enter the name and
location of the .DXF file you would like to create.



Synchronize / Database Connections - Access the Database Connection Manager, which allows
you to share SewerCAD data with external databases, spreadsheets, and other ODBC compliant
sources. Details of this comprehensive feature are explained in the chapter entitled "GIS and Database
Connections."

SewerCAD Main Window

19



Synchronize / Shapefile Connections - Access the Shapefile Connection Manager, which allows
you to share SewerCAD data with external GIS projects. Details of this feature are explained in the
chapter entitled "GIS and Database Connections."



Print - Print the current view of the project drawing to a printer. Profiles and tabular reports are
printed from their respective windows. The print command invokes the standard Print dialog, which
allows you to select things such as the printer to be used, printer properties, and the print range.
Shortcut Key:
Ctrl + P



Print Preview - Open the Print Preview dialog for the current view of the project drawing. This
feature allows you to see the drawing as it will be printed before sending it to the printer.
Toolbar Button:

2.3.3



Print Setup - Select the default printer for SewerCAD to use. You can also use this command to
change options related to the printer driver, such as resolution and portrait or landscape orientation.



Exit SewerCAD - Close the current project and exit SewerCAD. If you made any changes to the
current project, you will be asked if you want to save the project before you exit SewerCAD.
Shortcut Key:
Alt + F4



1, 2, etc. - The most recently opened project files appear at the bottom of the File menu. Using this file
list, you can quickly select and open a recently used file without navigating to its drive and directory.

Edit Menu
The Edit menu provides access to basic commands for controlling SewerCAD elements, such as element
navigation, selection, deletion, and undo and redo.


Undo [Last Action Performed] - Reverse the last reversible action performed. Reversible include
element creation, element deletion, element editing, and moves. The effects of some model actions
cannot be reversed, such as calculation, database synchronization, scenario creation and tabular edits.
Additionally, to ensure that the model is maintained in a consistent state, the undo/redo history is
flushed whenever an irreversible menu or button command is issued.
Shortcut Key:
Ctrl + Z (not available in AutoCAD Mode)



Redo [Last Action Undone] - Reverse the effects of the last undo action. Any action that can be
undone can be redone.
Shortcut Key:
Ctrl + Y (not available in AutoCAD Mode)



Cut (AutoCAD Mode Only) - Delete the selected entities and place them on the Windows clipboard.
These items can be pasted into other Window programs or back into AutoCAD.
Shortcut Key:
Ctrl+X



Copy (AutoCAD Mode Only) - Place a copy of the selected entities from the current AutoCAD
drawing to the Windows clipboard.
Shortcut Key:
Ctrl+C



Paste (AutoCAD Mode Only) - Place the items on the Windows clipboard into AutoCAD.
Shortcut Key:
Ctrl+V



Paste Special (AutoCAD Mode Only) - Place special items on the Windows clipboard, such as Excel
Spreadsheets and Word documents, into AutoCAD.

20

SewerCAD Main Window



Delete (Stand-Alone Mode Only) - Erase selected elements. Deleting an element removes it from all
aspects of the project, including all scenarios.
Shortcut Key:
Delete



Select / All - Select all of the elements in the current project.
Shortcut Key:
Ctrl + A (not available in AutoCAD Mode)



Select / By Element / All [Element Type] - Select all elements of a certain type, such as all pipes or
all junctions.



Select / By Selection Set - Select the elements contained in a predefined selection set.



Select / Clear Selection - Reset (empty) the current selection set.



Edit Element (AutoCAD Mode Only) - Open the element’s dialog. Select this item from the pulldown menu, and click the element you wish to edit.



Edit Elements (AutoCAD Mode Only) - Edit a group of elements. Select this item from the pulldown menu, then select a group of elements using the crosshairs or by windowing an area. After the
elements have been selected, the Table Manager dialog will appear.



Modify Elements / Change Pipe Width (AutoCAD Mode Only) - Modify the width of the AutoCAD
objects representing pipes in the current selection set.



Modify Elements / Scale Elements (AutoCAD Mode Only) - Scale the symbols representing the
elements in the current selection set.



Modify Elements / Rotate Elements (AutoCAD Mode Only) - Rotate the labels of the elements in the
current selection set.



Modify Pipes / Insert Bend (AutoCAD Mode Only) - Insert a bend along a selected Pressure Pipe
Element.



Modify Pipes / Remove Bend (AutoCAD Mode Only) - Delete a bend along a selected Pressure Pipe
Element.



Modify Pipes / Remove All Bends (AutoCAD Mode Only) - Delete all the bends along a selected
Pressure Pipe Element.



Modify Pipes / Change Widths (AutoCAD Mode Only) - Change the Width of the lines representing
pressure pipes.



Change Entities to Pipes (AutoCAD Mode Only) - Build network elements from AutoCAD entities.
This command will start the Polyline to Pipe Wizard, which will help you convert the desired
polyline data representing geographical data into pipes. A similar command called ‘Import Polyline to
Pipe’ is available in the Stand-Alone version under the File pull-down menu.



Find Element - Open the Find Element dialog, which allows you to locate an element and bring it to
the center of the drawing pane. This element search is based on the element label, and is not case
sensitive.
Shortcut Key:
Ctrl + F (not available in AutoCAD Mode)



Review Drawing - Open the Drawing Review window, which allows you to isolate elements that may
need to be scrutinized for potential problems, such as orphaned nodes, elements with messages, or
nodes in close proximity to each other.

SewerCAD Main Window

2.3.4

21

Analysis Menu
The Analysis menu holds items regarding calculations. These include such items as scenario access and
calculation command.


Scenarios - Opens the Scenario Manager, where you can create, compare, and otherwise manipulate
scenarios.
Toolbar Button:



Alternatives - Provides access to the Alternative Manager, where you can add, delete, and otherwise
manipulate alternatives.



Patterns - Opens the Pattern Manager where you can create and edit diurnal loading patterns for use
with extended period simulations.



Extreme Flows - Opens the Extreme Flows Manager where you can create a list of extreme flow
setups. Flow setups can then be associated with a scenario to control the peaking of the base sanitary
loads.



Pattern Setups - Opens the Pattern Setup Manager where you can associate diurnal patterns with
the appropriate unit sanitary loads for a given scenario.



Default Design Constraints - Specify constraints for pipes, nodes, and inlets to be used during an
automatic design and while checking constraints for an analysis calculation.



Compute Costs - Opens the Cost Manager to view, edit, or perform Cost Estimating calculations.
Toolbar Button:



Compute - Opens the Calculation Dialog. This dialog gives you access to items such as referenced
alternatives and calculation options.
Toolbar Button:

2.3.5

View Menu
In both AutoCAD and Stand-Alone mode, the View menu provides access to tools dealing with the
drawing pane, toolbar visibility, and so forth.
In Stand-Alone mode, you are provided with the following tools:


Pan - Upon selection hold down the left mouse button to move the drawing
Toolbar Button:
Shortcut Key:



Hold down the mouse wheel.

Zoom In - Enlarge the current view of the drawing.
Toolbar Button:
Shortcut Key:

+ (Keypad)

22


SewerCAD Main Window

Zoom Out - Reduce the current view of the drawing.
Toolbar Button:
Shortcut Key:



- (Keypad)

Zoom Window - Activate the user-defined zoom tool. This tool enables you to select the corners of
the area within the drawing pane that you wish to enlarge.
Toolbar Button:



Zoom Extents - Reset the drawing zoom factor such that all elements are displayed in the drawing
pane.
Toolbar Button:



Zoom Previous - Return the drawing pane to the most recent view.
Toolbar Button:



Zoom Center - Open the Zoom Center dialog, which enables you to specify the central coordinates
and zoom factor to change the view in the drawing pane.



Aerial View - Enable or disable the Aerial View window. This window allows you to display a
second view of the drawing at a larger scale.



Quick View - Enable or disable the Quick View window, which allows you to quickly view input and
output data for any element.
Toolbar Button:



Toolbars / Standard - Toggle the display of the Standard toolbar at the top of the window, which
provides shortcuts to the most commonly used commands.



Toolbars / Analysis Toolbar - Toggle the display of the Analysis toolbar, which includes the scenario
selection list, as well as the time step selection list if applicable.



Status Pane - Toggle the display of information at the bottom of the window regarding your current
project.



Background - Toggle the visibility of the project’s .DXF background. If there is no .DXF background
specified for the current project, this menu item will be disabled.
In AutoCAD mode, refer to the AutoCAD on-line help.

2.3.6

Tools Menu
The Tools menu allows you access to many useful features for viewing results, as well as selecting the
tools used to generate network elements and graphical annotations within the drawing pane.


Selection Sets - Opens the Selection Set Manager, which allows you to predefine a group of network
elements that you want to manipulate together.

SewerCAD Main Window


23

Color Coding - Opens the Color Coding dialog. Color coding can be used to control the geographical
display of elements based on value ranges such as pipe diameter and hydraulic grade.
Toolbar Button:



Element Annotation - Provides access to the Element Annotation dialog, which allows you to
display additional element attribute labeling such as pipe diameter and outlet total flow.
Toolbar Button:



Profiling - Opens the Profiles dialog where you can create new profiles or view previously created
ones.
Toolbar Button:



Diversion Network - Displays a view of the Diversion Network, which is implicitly defined from the
diversion targets.
Toolbar Button:



Relabel Elements - Open the Relabel Elements dialog, which enables you to renumber some or all of
your project elements.



Element Labeling - Set the format for the labels applied to elements as they are added to the drawing.



Prototypes - Specify the default values for new network elements.



Engineering Libraries - Declare the paths to and edit the libraries used in this project.



User Data Extension - Open the User Data Extension dialog, where you can add and define custom
data fields. For instance, you can add new fields such as the pipe installation date.



FlexUnits - Open the FlexUnits dialog, where you can control units and display precision for any
parameter. You can also change the unit and display precision of variables from several other areas
within the program.



Layout / Select - Activates the Selection tool, which is used to select elements within the drawing
pane. Once elements are selected, they can be edited, moved, and otherwise manipulated.
Toolbar Button:



Layout / Pipe - Activates the Pipe Layout tool, which enables you to connect nodes (new or existing)
with a new pipe element.
Toolbar Button:



Layout / Manhole - Activates the Manhole tool, which is used to add manhole elements to the
project.
Toolbar Button:



Layout / Junction Chamber - Activates the Junction Chamber tool, which is used to add junction
chamber elements to the project.
Toolbar Button:

24


SewerCAD Main Window
Layout / Wet Well - Activates the Wet Well tool, which is used to add wet wells to the project.
Toolbar Button:



Layout / Pump - Activates the Pump tool, which is used to add pumps to the project.
Toolbar Button:



Layout / Pressure Junction - Activates the Pressure Junction tool, which is used to add pressure
junctions to the project.
Toolbar Button:



Layout / Outlet - Activates the Outlet tool, which is used to add outlet elements to the project.
Toolbar Button:



Layout / Graphic Annotation - Activates various annotation tools, which enable you to add lines, text
elements, and other non-hydraulic elements to the project drawing.
Toolbar Button:



Layout / Legend - Activates tools that enable you to add legends to the project drawing, such as a pipe
or node color-coding legend.
Toolbar Button:

2.3.7



Options - Activates the Options dialog, where you can customize the Global, Project, and Drawing
Options for your projects.



Element Properties (AutoCAD Mode only) - Opens a dialog that allows you to establish the layers
and style of SewerCAD hydraulic elements and text.



Preferences (AutoCAD Mode only) - Opens the AutoCAD Preferences dialog. See the AutoCAD online help for more information.

Report Menu
The Report menu provides access to a collection of preformatted textual and graphical reports.
Furthermore, it provides access to FlexTables, which enable you to create your own custom reports.


Element Details - Opens the Detailed Reports dialog, which enables you to print detailed reports for
any set of elements.



Element Results - Opens the Analysis Results Report dialog, which enables you to print reports of
the results for any set of elements.



Element Hydrographs - Opens the Graph Setup dialog from which you can generate hydrographs
for multiple elements within the hydraulic network over multiple scenarios.



Element Graphs / Gravity Pipes - Opens the Graph Setup dialog from which you can graph various
attributes associated with gravity pipes over time.



Element Graphs / Pressure Pipes - Opens the Graph Setup dialog from which you can graph
various attributes associated with pressure pipes over time.



Element Graphs / Manholes - Opens the Graph Setup dialog from which you can graph various

SewerCAD Main Window

25

attributes associated with manholes over time.


Element Graphs / Junction Chambers - Opens the Graph Setup dialog from which you can graph
various attributes associated with junction chambers over time.



Element Graphs / Wet Wells - Opens the Graph Setup dialog from which you can graph various
attributes associated with wet wells over time.



Element Graphs / Pumps - Opens the Graph Setup dialog from which you can graph various
attributes associated with pumps over time.



Element Graphs / Pressure Junctions - Opens the Graph Setup dialog from which you can graph
various attributes associated with pressure junctions over time.



Element Graphs / Outlets - Opens the Graph Setup dialog from which you can graph various
attributes associated with outlets over time.



Tables - Provides access to the Table Manager, which enables you to open predefined tables or
generate custom tables.
Toolbar Button:

2.3.8



Scenario Summary - Generates a report for the current scenario, including things such as referenced
alternatives and calculation options.



Project Inventory - Generates a report summarizing the project elements, including the number and
breakdown of pipes and the number of manholes.



Plan View - Generates plan view printable reports of the network, for either the current drawing
display (Current View) or the entire drawing extents (Full View).

Draw Menu (in AutoCAD Mode Only)
The Draw menu is actually an AutoCAD menu that is accessible in the current program.
You can add additional AutoCAD menus to your Haestad Methods' application menus using
AutoCAD's 'menuload' command. See the AutoCAD documentation for more information.

2.3.9

Help Menu
The Help menu contains items that relate to on-line documentation for SewerCAD. Help includes the
information contained in the printed documentation, as well as updated information and interactive
tutorials.
Help menu items can also be accessed from the Help button:



Contents - Opens the table of contents for the on-line help.



How to Use Help - Provides access to instructions for using the help system.



Release Notes - Provides the latest information on the current version of SewerCAD. This topic,
which takes the place of a ReadMe file, may include information about new features, tips, performance
tuning, and other general information.



Services / Contents - Connects you to the Haestad Methods Services page, where you can access
information on our products and Continuing Education.

26

SewerCAD Main Window



Services / Multimedia CD - Opens a comprehensive demonstration of related Haestad Methods'
software products.



Services / Haestad.com - If you are connected to the Internet, this will take you to Haestad Methods’
website for product updates and other services.



Services / CivilProjects.com - If you are connected to the Internet, this will take you to our Civil
Projects website, which was created as a special service for our friends and clients in the Civil
Engineering community. This site contains RFPs and RFQs to help you find the work you are looking
for.



Welcome Dialog - Opens the Welcome Dialog, which is normally shown at program startup.



Tutorials - Provides access to the interactive tutorials, which guide you through many of the
program’s features. Tutorials are a great way to become familiar with new features.



Using SewerCAD - Opens a help topic with an introduction to SewerCAD and related elementary
information.



How Do I - Provides instructions for common tasks you can perform within the program.



About SewerCAD - Opens a dialog displaying product and registration information.

2.4 SewerCAD Toolbars
2.4.1

Toolbar Button Summaries
The toolbars are grouped based on functionality, so element creation tools are located together on the tool
palette, results tools are on the tool pane, and so forth.
In AutoCAD mode, some tools are provided by AutoCAD itself, so they are not included on the
SewerCAD toolbars.

2.4.2

Tool Pane Summary
The tool pane contains buttons for project management, data management, and presentation of results.
File Tools (Stand-Alone Only)
New - Create a new project.
Open - Open an existing project.
Save - Save the current project.
Print Preview - The print preview of the current view.
Zoom and Pan Tools (Stand-Alone Only)
Pan - Pan or move around in the drawing

SewerCAD Main Window
Zoom Extents - Zoom to the full extents of the drawing.
Zoom In
Zoom Out
Zoom Window - Zoom to a selected area.
Zoom Previous - Zoom to the previous view.
Calculation Tools
GO - Open the Calculation dialog for the current scenario.
Data Management and Reporting Tools
Tabular Reports - Open the Table Manager.
Annotation - Annotate elements with input or output data.
Profile - Open the Profile dialog to create new profiles or view previously created
ones.
Diversion Network - Open a plan view of the diversion network.
Quick View - Open the Quick View window for easy data viewing.

Updates and Help Tools
Globe - If you are connected to the Internet, this will take you to Haestad Methods’
website for product updates and other services.
Help - Access the on-line help system.

27

28

2.4.3

SewerCAD Main Window

SewerCAD Tool Palette
The tool palette contains a Select tool, Network Element tools, and Annotation tools.


The Select tool allows you to select elements for group editing, detailed reporting,
deleting, or moving elements.



The Network Element tools allow you to add elements to your network. These tools can
also be used to split pipes and morph nodes.



The Annotation tools can be used to add polylines, borders, and text to your drawing.
You can also add a link or node color-coding legend using the Legend tool.
Click a tool to select it as the active tool. In Stand-Alone mode, when a tool is selected
it will be highlighted, and the cursor appearance will change to reflect the active tool.
In Stand-Alone mode, right-click the tool palette to access the Prototype Manager for
setting the default data for each type of network element.

2.4.4

Analysis Toolbar
The Analysis toolbar displays the active scenario, provides a means for changing the active scenario, and
provides access to the Scenario Manager. It also allows you to scroll through and animate time steps
using the VCR based controls. All input and output information displayed in the tables, profiles, element
dialogs, and annotation will be for the active scenario and time step shown in the Analysis toolbar.

You can change the current scenario from the list box, and you can access the Scenario Manager by
clicking the folder button.
You can access the Cost Manager by clicking the folder with the dollar sign.

2.4.5

SewerCAD VCR Controls
At various locations throughout SewerCAD, such as the Analysis Toolbar, you can scroll and animate
through time steps. You can do so by using the following VCR style controls:

Play / Stop - These buttons will stop and play an animation at the increment selected in
the increment pull-down menu.
Start Time / Stop Time - These buttons will proceed to the first and final time step
respectively.
Decrement / Increment - These buttons will proceed to the previous or next time step
based on the increment selected in the increment pull down menu.
Time Selector - This pull-down menu allows you view a particular time step.
Increment Selector - This pull-down menu allows you to select the increment by which
to scan through animations, and individual time steps.

SewerCAD Main Window

29

By clicking the down arrow next to the Play button you can access the following Animation Options:

2.4.6



Animation Delay - Opens a dialog that allows you to set the delay between animated frames.



Animate All Windows - If this option is selected, then every window capable of being animated will
animate when the play button is clicked. If the option is not selected then only the current window will
animate.

Other Toolbar Buttons
Some of the following toolbar buttons appear on secondary windows, such as the Print Preview window
and the Profile window, available throughout the program:


File



Print



Print Preview



Copy to Clipboard



Undo



Redo



Options



Page Up/Down



Close



Help

Print Preview
Open a Print Preview on the contents of the current window.

Page Up/Down
Navigate between pages of a multi-page report.

File
Export the data in the current window to a file format that can be used by other applications (such as .DXF
and ASCII text files).

Copy to Clipboard
Copy data to the clipboard, where it can be pasted into most Windows-based spreadsheet, database, and
word processor applications.

30

SewerCAD Main Window

Print
Print the contents of the current window.

Undo
Undo the previous action.

Redo

Redo the previously undone action.

Options
Options vary depending on the context. They may include things such as printer setup, or graph options for
the current window.

Close
Close the current window.

2.5 The Status Bar
2.5.1

General Status Information
General status information includes messages that relate to the user’s current activities. These messages
consist of information such as pull-down menu command descriptions, and indications regarding the
progress of an executing command.

2.5.2

DXF Background Status
This area of the status bar simply indicates whether a .DXF background is currently visible for the active
project.

2.5.3

Cursor Location
The status bar displays the current X and Y (or Northing and Easting) coordinates for the cursor’s position
within the drawing pane.

SewerCAD Main Window

2.5.4

31

Calculation Results Status
In Stand-Alone mode, if the current calculation results are out-of-date or otherwise invalid, an indicator
will appear in the status bar that signifies that the results no longer match the state of your input data. If the
results are currently valid, no such indicator will appear.

2.5.5

File Status
If changes have been made since the last time the project file was saved, an image of a diskette appears in
the status pane. If the file is currently in a saved state, no such image will appear.

Notes

Chapter 3 – Quick Start Lessons

33

Chapter 3
Quick Start Lessons
3.1 Overview
The purpose of Chapter 3 is to provide step-by-step lessons to get you familiar with some of the features
and capabilities of SewerCAD. The lessons serve as a means to get you started exploring and using the
software. We have included sample files located in your Haestad\SWRC\Lesson directory for you to
explore and experiment with. Don’t forget to run our online tutorials, and, if you need help, press F1 (or
right click) to access our context sensitive on-line help.
In order to follow these tutorials, you can either do them in sequence, since each tutorial uses the
results of the previous ones, or start lesson 2, 3, 4, and 5 with the files located in
Haestad\SWRC\Lesson.

3.2 Lesson 1 - Creating a Schematic Network
SewerCAD is an extremely efficient tool for laying out a sanitary sewer model. It is easy to prepare a
schematic model and let SewerCAD take care of the link-node connectivity.
You do not need to be concerned with assigning labels to pipes and nodes, because SewerCAD will handle
this internally. When creating a scaled drawing, pipe lengths are automatically calculated from the position
of the pipes’ start and stop nodes on the drawing pane. Since this example is a schematic (not scaled)
layout, you will need to enter the pipe lengths.
In this lesson we will layout and analyze the following schematic network.

If, at any time during this lesson, the program asks "Do you wish to reset all calculated results to
N/A?" click NO.

34

Chapter 3 – Quick Start Lessons

Part 1 - Creating a New Schematic Project File

AutoCAD specific

Stand-Alone specific

Start SewerCAD Stand-Alone. If the Welcome to SewerCAD dialog appears, click the
Create New Project button. If it does not appear, choose New from the File pull-down
menu. Enter a file name such as ‘Lesson.swr’ for your project and click Save.
In Stand-Alone mode, the Welcome dialog can be obtained by selecting Tools / Options from the
pull-down menus and choosing the Global tab. Set the Welcome Dialog field to Show Welcome
Dialog on startup.
The lessons are based on a model with 6 pipes. This was done in order to illustrate the different
element types and different concepts in the network layout within SewerCAD. If you have a
smaller version of the product you can delete one of the manholes before calculating. To do so
simply select the manhole and press the "Delete" key. The concepts will be the same.

Start SewerCAD for AutoCAD and choose New on the File pull-down menu to create a
new file. Click No when prompted to save the current drawing. In the Create New
Drawing dialog, click the Use a Template button. In AutoCAD r14 select the
SWRC14.dwt. In AutoCAD 2000 select the SWRC15.dwt file.
If you are in AutoCAD 2000 and you get prompted at the command line for a template
instead of getting the Create New Drawing dialog, click on the Escape button. Type
options at the command prompt and on the System tab, set the Show Startup dialog toggle
to ON. When asked if you would like to setup the project, click Yes. If you are in
AutoCAD 2000i and the AutoCAD Today window comes up, select the Create Drawings
Tab and select the SWRC15.dwt template.

The remaining commands are the same in Stand-Alone and AutoCAD mode.


Enter information about the project (optional). Click the Next button.



Choose your desired settings. For this lesson, use the program default values. Click on the Next
button.



Select the Schematic radio button located under the Drawing Scale option. Click the Next button to
accept the rest of the default values.



The element prototype buttons allow you to set default values for each element type. We will use the
default prototype values in this lesson. Click the Finished button.

Part 2 - Laying Out the Network
In this example we will use Metric units. Before laying out any element, select Tools / Options from the
pull-down menu and choose the Global tab. Set the global unit system to System International, and click
OK.
To draw the skeletonized sewer network shown previously, select the Pipe Layout tool
from the
toolbar. Then move the cursor onto the drawing space and click once to place a manhole to represent the
manhole labeled MH-1. Right-click and select wet well from the pop-up menu. Move the cursor to the

Chapter 3 – Quick Start Lessons

35

approximate location of the wet well, WW-1, and click once to place it. Now, place the pump, pressure
junction, and the outlet by right clicking, selecting the appropriate element from the pop-up menu, and then
clicking once to place each element.
Wet wells represent the transition point between the gravity system and the pressure system. Similarly,
manholes and junction chambers can represent the transition from a pressure system to the gravity system.
SewerCAD automatically creates either gravity pipes (depicted by parallel lines) or pressure pipes
(depicted by a single line) depending on the pipe’s upstream and downstream nodes.
Place manhole, MH-2, using the Pipe Layout tool. Right-click and select Junction Chamber from the
pop-up menu. SewerCAD allows you to split any pipe in two. To insert the junction chamber, click the
middle of pipe P-1. A dialog will pop up asking whether you wish to split the pipe and insert a junction
chamber. Click Yes. Right-click and select Done from the pop-up menu to terminate the pipe layout
command. Click JC-1 and drag it down so your network matches the layout shown above.
Part 3 - Entering Data
There are five ways to enter and modify element data in SewerCAD:


Dialogs - You may use the Selection tool and double-click an element (single click in AutoCAD) to
bring up its editor. In AutoCAD, click the element once with the Selection tool to open the element’s
editor.



Quick View Window - Click the Quick View Window button in the main toolbar. You can then
select an element and modify any of the white fields under the Input tab.



FlexTables - You may click on the Tabular Reports button to activate dynamic tables that allow you
to edit and display the model data in a tabular format. You can edit data as you would in a
spreadsheet.



Database Connections - The database connection feature allows you to import and export element
data directly from external sources such as Excel spreadsheets, GIS, Jet Databases like Microsoft
Access, and many others. This is further explained in the chapter on database connections.



Alternative Editors - Alternatives are used for entering data for different "What If?" situations for use
in Scenario Management. This is covered extensively in the Scenario Management chapter and Lesson
3.

Part 4 - Entering Data through Dialogs
To access an element’s dialog in Stand-Alone mode and AutoCAD 2000i, simply double-click the element
with the cursor. In AutoCAD 2000 and R14, first click on the Selection tool on the toolbar, then click the
element whose attributes you wish to modify.
Open the editor of the outlet, O-1, and select the General tab. Simply enter the data including ground
elevation, rim elevation, and sump elevation as outlined in the following Outlet Data table. If the Set Rim
to Ground Elevation box is checked, SewerCAD will automatically set the rim elevation to the ground
elevation. Finally, select Free Outfall from the Tailwater Conditions choice list.

36

Chapter 3 – Quick Start Lessons

Outlet Data
General Tab

Outlet
O-1

Ground
Elevation
(m)
16

Rim
Elevation
(m)
16

Sump
Tailwater
Elevation Condition
(m)
14
Free Outfall

Click OK. All other elements can be modified the same way.
Now enter the data for the manholes and the junction chamber as outlined in the Manhole data and Junction
Chamber data tables below. Keep in mind that the headlosses are accessed by clicking the Headlosses tab
at the top of the dialog. Select Standard from the list of available headloss methods in the Headloss
Method field. Then enter the headloss coefficient for each structure.

Manhole Data
Manholes

MH-1
MH-2

Ground
Elevation
(m)
11.1
11.1

General Tab
Rim
Elevation
(m)
11
11.1

Headlosses Tab
Sump
Elevation
(m)
9
9

Diameter
(m)
1
1

Headloss
Method
Standard
Standard

Headloss
Coefficient
0.25
0.25

Chapter 3 – Quick Start Lessons

37
Junction Chamber Data

General Tab
Ground
Top
Bottom Structure
Elevation
Elevation Elevation Diameter
(m)
(m)
(m)
(m)
12
11
9.2
1

Junction
Chambers
JC-1

Headlosses Tab
Headloss Headloss
Method
Coefficient
Standard

0.5

Open the element editor for the wet well, WW-1. Under the General tab, enter the station and ground
elevation for the wet well given in the Wet Well Data table below. Click the Section tab to enter in the wet
well’s geometric characteristics, which are given in the Wet Well Data table below. Use the default values
for the other parameters. Click OK to exit the dialog.

Wet Well Data

General Tab
Wet Wells Station
(m)
WW-1
0+00

Section Tab
Ground
Max
Initial
Min
Base
Elevation
Section
Elevation Elevation Elevation Elevation Diameter
(m)
(m)
(m)
(m)
(m)
(m)
10.5
Constant Area
10
8
6
6
3

Open the element editor for the pump, PMP-1. Select Standard (3 Point) from the Pump Type choice
list. Enter the pump elevation and the discharge curve as given in the Pump Data table below. Also, notice
the pump has an upstream pipe and a downstream pipe to define the direction. If the pump is ever going in
the wrong direction, simply click the Reverse button to switch it. In this example, the upstream pipe
should be FM-1 and the downstream pipe should be FM-2. Click OK to exit the dialog.

Pump Data

General Tab
General Tab
Pump
PMP-1

Elevation
Pump
(m)
Type
7.8
Standard 3 Point

Shutoff:
Design:
Max. Operating

Head
(m)
22.67
17
0

Discharge
(m 3/min)
0
24
48

Open the element editor for the pressure junction, J-1. Enter the value for elevation as given in the Pressure
Junction Data table below. Click OK to exit the dialog.

Pressure Junction Data
Pressure
Junction
J-1

General Tab
Elevation
(m)
14.2

Part 5 - Steady State Loading
In SewerCAD, loading is categorized as either a sanitary load or a wet weather load. Sanitary (dry
weather) loads occur independent of the weather, such as wastewater from a subdivision. Wet weather

38

Chapter 3 – Quick Start Lessons

loads such as pipe infiltration and inflow at nodes are directly related to the rainfall in the area. This part of
the lesson deals with sanitary loads.
Loads can be applied to manholes, wet wells, and pressure junctions. The program has been designed so
that all loads are designated at a node using the same procedure. To access an element’s loading data, open
the editor for the node of interest and click the Loading tab at the top of the dialog.
SewerCAD defines loads by Unit Sanitary (Dry Weather) Load and the Loading Unit Count. The Unit
Load represents the amount of load per a given unit. For example, in average income housing, each
resident contributes 280 l/d to the sanitary sewer. The Loading Unit Count would be the number of units.
Say 40 residents live in a subdivision of average income housing. The total load would be the Unit Load
multiplied by the Loading Unit Count. Thus, the total load is 40 residents * 280 (l/d)/resident which equals
11,200 l/d.
Open the editor for MH-1 and click the Loading tab at the top of the dialog.

Click the Add button next to the Sanitary (Dry-Weather) Flow pane. In the Edit dialog, select Unit
Load - Unit Type & Count as the Load Definition. Notice you can also enter in a hydrograph as a
sanitary load. We shall explore time based loading further in lesson 5 on running EPS simulations. Click
OK. In the Base Load dialog that appears, select Apartment from the Unit Sanitary (Dry Weather)
Load pull-down menu. Then enter a Loading Unit Count of 2000. Click OK to return to the Loading tab
on the Manhole editor.

Chapter 3 – Quick Start Lessons

39
Loading Data

Node
MH-1

Loading Tab
Unit Dry
Weather Load
Apartment
Home(Average)
Home(Better)

Loading Unit
Count
2000
3000
2000

Loading Unit
resident
resident
resident

MH-2

Resort
Hotel (Residential)

2000
1000

guest
guest

WW-1

Theater
Shopping Center per Employee

200
60

customer
employee

J-1

School (Medium)

500

student

Fill in the rest of the loads for MH-1 as outlined in the Loading Data table above, entering them into
successive rows as they are created on the table. Click OK to exit the dialog.
After you have completed supplying the loading for MH-1, apply loads to MH-2, WW-1, and J-1 exactly
the same way. All the loading data is outlined in the Loading Data table above.
Part 6 - Extreme Flow Factors
After all loads have been applied you can specify how those average loads relate to the peak load. This is
done through the Extreme Flow Setup Manager, which is accessed by selecting Analysis / Extreme
Flows from the pull-down menus. In the Extreme Flow Setup Manager double-click the Base Extreme
Flow Setup. In the Extreme Flow Setup dialog you specify which Extreme Flow method is applied and
any associated constants and adjustment multipliers.

Under the Used Loads tab the Unit Loads currently used in the model are presented. If you wanted to
apply Extreme Flow Methods to unit loads that have not been used yet, you would click the Unused Loads
tab.

40

Chapter 3 – Quick Start Lessons

To apply an extreme flow method to a unit load, simply click the field under the Extreme Flow Method
column and select the method you wish to use from the choice list. For this example, apply the Babbitt
equation to all the used unit loads. You may speed this up by right clicking anywhere in that column,
selecting Global Edit… from the pop-up menu, selecting Babbitt from the Extreme Flow Method dropdown box, and clicking OK. In this case, we wish to use the peaking factor calculated by the Babbitt
method without any adjustment. Therefore, do not alter the default adjustment multiplier of 1.
Click OK to exit the Extreme Flow Setup dialog. Click OK to exit the Extreme Flow Setup Manager.
Part 7 - Entering Data through the FlexTables
Often it is more convenient to enter data for similar elements into a tabular form rather than to individually
click every element, enter the data into the dialog, and then click the next element. To access the tabular
report, click the Tabular Reports button

on the toolbar.

Click the Gravity Pipe Report and click OK. Enter data as you would into a spreadsheet. The yellow
fields are not editable and the white fields are. For each of the three gravity pipes enter the upstream and
downstream inverts, the section size, the section type, and the pipe material as outlined in the Gravity Pipe
Data table below. Leave other data to default values. The gravity pipes may not be in alphanumeric order
in the table. To sort the table by pipe label, right-click the Label column heading. Select Sort / Ascending
from the pop-up menu that appears. You may want to maximize the window to be able to view it better.
The pipe lengths and bend angles are either calculated from the pipe orientation and position on the
drawing space or they are user-defined. To make the values user-defined; check the boxes in the UserDefined Length and User-Defined Bend Angle columns of the FlexTable. This makes the bend angle and
length fields editable. Now enter the length and bend angles for the gravity pipe given in the Gravity Pipe
Data table below.

Gravity Pipe Data

Gravity
Pipe

P-1
P-2
P-3

Length
(m)

Bend
Angle
(radians)

Section
Shape

Material

Section
Size

100
70
100

0
0
0.8

Circular
Circular
Circular

Concrete
Concrete
Concrete

200 mm
200 mm
200 mm

Upstream Downstream
Invert
Invert
Elevation
Elevation
(m)
(m)

10
9.5
10

9.5
9.1
9.5

The default roughness factor is based on the material chosen. If you want to add a column in order to see
or change the roughness factor being used, you can easily add this field to the FlexTable. First, click the
Options button at the top of the table and select Table Manager from the pull-down menu. Highlight
Gravity Pipe Report, click the Table Management button, and select Edit. Find the Mannings n column
in the Available Columns list and double-click it. Manning’s n will show up at the end of the Selected
Columns list. Click OK to exit the Table Setup dialog. Click OK on the Table Manager dialog to return
to the Gravity Pipe table. The Mannings n values are displayed in the very last column of the report.
Leave the other parameters set to the current values.

Chapter 3 – Quick Start Lessons

41

To go to the Pressure Pipe table to enter the data for pressure pipes, first click the Options button at the
top of the Gravity Pipe table and select Table Manager from the pull-down menu. Select Pressure Pipe
Report from the list of available tables and click OK. Now fill in the data as outlined in the Pressure Pipe
Data table below.

Pressure Pipe Data
General Tab
Pressure
Material
Diameter
Pipe
(mm)
FM-1
Ductile Iron
200
FM-2
Ductile Iron
200
FM-3
Ductile Iron
200

Upstream Downstream
Invert
Invert
(m)
(m)
6
7.8
7.8
13
13
14

Length
(m)
1
200
100

There are two things to keep in mind when entering information about pressure pipes. First, invert
elevations are calculated based on the elevations of upstream and downstream nodes, so they are already
pre-entered. Invert elevations are only editable if the upstream or downstream node is a wet well or a
gravity node. Secondly, all pressure pipes in SewerCAD are circular, so only a diameter is entered. Once
all the data is entered click the Close button at the top of the dialog.
As you can see, all element input data can be entered through the FlexTables.
Part 8 - Entering Infiltration Data Into Gravity Pipes
To account for infiltration into gravity pipe P-1, open the pipe’s editor and click the Infiltration tab. Select
Pipe Length from the choice list labeled Infiltration Load Type. The Pipe Length section will appear.
In this section, select an Infiltration Loading Unit of "m." Then type an Infiltration Rate per Loading
Unit of 0.25 l/d. Click OK to exit. Now, enter the infiltration data for the other two pipes as outlined in
the Infiltration Data table below.

42

Chapter 3 – Quick Start Lessons
Infiltration Data
Infiltration Tab
Gravity
Pipe
P-1
P-2
P-3

Infiltration
Infiltration Infiltration
Rate per
Type
Unit
Loading Unit(l/d)
Pipe Length
m
0.25
Pipe Length
m
0.05
Pipe Length
m
0.03

Part 9 - Analyzing the System
Click the GO button to bring up the Calculation dialog. Make sure that the Calculation Type is marked
as Steady State.

Click the GO button on the dialog to analyze the model. When calculations are completed, a Results
report is displayed.
The Results tab displays a summary of model results. Scroll through the summary to get an idea of the
results that are given.
Notice the light displayed on the Results tab of the dialog. You can quickly tell if there were warnings or
failures with a glance at the light. A green light indicates no warnings or failures; a yellow light indicates
warnings, while a red light indicates problems. The coloring scheme is used with the folders in the results
hierarchy. So if a particular folder is yellow for a calculation step, there are warnings associated with that
step. Simply double click one of the folders to view the results.

Chapter 3 – Quick Start Lessons

43

Click the Element Messages button to display all the messages generated for individual elements during
the run in a more convenient tabular format. You can exit the Element Calculation Message Browser by
clicking the Close button.
Click Close when you are done to exit back to the drawing pane. After a model run all the calculated fields
in dialogs and tabular reports will display results. See Lesson 4 for an overview of the output options
available.
As you can see from looking at the results, the performance of the gravity portion of this sewer is
unacceptable for implementation because of flooding and high pressures at the junction chamber.
SewerCAD’s automatic design capabilities, which are outlined in Lesson 2, can quickly find an optimal
solution.
Before proceeding to the next lesson, save this project. For example, save it as lessons.swr in Stand-Alone
mode, or lessons.dwg in AutoCAD mode.

3.3 Lesson 2 - Automatic Design
This lesson will illustrate how SewerCAD can automatically design all or parts of the gravity portion of a
sanitary sewer system within the design constraints set by the user. After specifying parameters such as
lengths, ground elevations, and boundary conditions, SewerCAD will work to find a satisfactory design.
In this lesson, we will use this feature to develop a new design to replace the undersized sanitary sewer
system created in Lesson 1.
If, at any time during this lesson, the program asks, "Do you wish to reset all calculated results to
N/A?" click NO.
This lesson is based on the project created in Lesson 1. If you have not completed Lesson 1, open the
project lesson2.swr (lesson2.dwg in the AutoCAD version) from the SWRC / Lesson directory.

44

Chapter 3 – Quick Start Lessons

Part 1: Designating Design Constraints
SewerCAD requires parameters by which to measure the validity of a possible design. These parameters,
or design constraints, can either be set locally for each individual element or they can be entered as default
design constraints.

To enter the default design constraints, select Analysis / Default Design Constraints from the pull-down
menu. On the Gravity Pipe tab, enter the minimum and maximum flow velocities, slopes, and covers that
the newly designed pipe’s characteristics should fall between. These values are listed in the Design
Constraint Data table below.

Design Constraint Data

Velocity
Cover
Slope

Gravity Pipe Tab
Minimum Maximum
0.60
4.00
0.70
4.00
0.005
0.10

m/s
m
m/m

You could further hone the design with the Extended Design features on the right side of the dialog. Check
the box next to one of three extended design criteria and enter a constraining value to have SewerCAD
utilize the feature.
Click the Gravity Structure tab to set constraints for gravity structures. Set the Pipe Matching constraint
to Inverts and the Matchline Offset to 0.0 m. From this, SewerCAD knows to set the inverts of the
incoming pipe at the same elevation as the invert of the outgoing pipe for the same structure. Click Close
to exit the dialog.
Consider that the downstream invert of Gravity Pipe, P-2, entering into the wet well, WW-1, is at a known
elevation and should not be adjusted by SewerCAD’s automatic design process. In this situation, you can
locally specify that SewerCAD not design the downstream invert of P-2. Enter the Gravity Pipe Editor
for P-2 by either double-clicking the pipe (Stand-Alone mode) or by first choosing the Selection tool and
clicking the pipe once (AutoCAD mode). Click the Design tab. In the upper left corner of the dialog,
uncheck the box next to Design Downstream Invert.
If the Specify Local Constraints box is checked, you could then fill in design constraints specific to the
element whose dialog you are currently in. This feature is located under the Design tab for every gravity
element in SewerCAD. Click OK to exit the Gravity Pipe Editor. Click OK to exit the dialog.
Part 2: Design
To run the Automatic Design analysis, click the GO button on the toolbar. Click the Design check box in
the Steady State section of the dialog. Then click the GO button to run the design. You will be asked
whether you would like to create a new Physical Alternative. Alternatives are groups of data that describe
a specific part of your model such as physical data, loading data, and infiltration data. Alternatives will be

Chapter 3 – Quick Start Lessons

45

discussed further in Lesson 3. By clicking Yes, the model remembers the initial design as well as the new
design for the sake of comparison. In this case click No and allow the model to overwrite the current
physical alternative.
After the model runs, the green light on the Results tab indicates that there are no warnings for the design
formulated by SewerCAD. SewerCAD was able to find a sewer configuration that did not cause any
warning conditions and that did not violate any design constraints. Sometimes, however, it is impossible to
find a solution that does not violate one of the design constraints, in which case there will be a warning to
that effect presented under the Results tab. For more detailed information on how the program uses design
constraints see Appendix B of the help. Click the Close button.

Save this project before proceeding to Lesson 3.
This lesson introduced one possible application of the automatic design feature. This is a powerful tool that
will save you time and effort. Spend some time to learn more about this feature by experimenting with the
software, and if you have any questions press the F1 key to access our context sensitive on-line help. See
Lesson 3 for more information on SewerCAD’s scenario management feature.

3.4 Lesson 3 - Scenario Management
One of SewerCAD’s many powerful and versatile project tools is Scenario Management. Scenarios allow
you to calculate multiple "What If?" situations in a single project file. You may wish to try several designs
and compare the results, or analyze an existing system using several different loading possibilities and
compare the resulting profiles. A scenario consists of a group of alternatives, which are groups of actual
model data. Both scenarios and alternatives are based on a parent/child relationship where child scenarios
and alternatives inherit data from the parent scenarios and alternatives.
In this lesson we will use Scenario Management to set up the scenarios needed to test four "What If?"
situations for the purpose of analyzing a new sanitary sewer system design. At the end of the lesson, we
will compare all of the results using the Scenario Comparison tool.
If, at any time during this lesson the program asks, "Do you wish to reset all calculated results to
N/A?" click NO.

46

Chapter 3 – Quick Start Lessons

Part 1 - Opening the Project File
For this lesson we will use the system designed in Lesson 2. Click the Open Existing File button in the
Welcome dialog, or select File / Open from the pull-down menus to bring up the Open Project File
dialog. Open the project you saved from Lesson 2, or find lesson3.swr (lesson3.dwg in the AutoCAD
version) in the SWRC / Lesson directory.
In Lesson 2 we designed the gravity portion of this system using the automatic design tool. In this lesson,
we will use scenario management to model different force main designs.
Part 2 - Creating Alternatives
First, we need to set up the required data sets (alternatives). An alternative is a group of data describing a
specific part of the model. There are eleven alternatives: Physical Properties, Sanitary (Dry Weather)
Loading, Infiltration and Inflow Loading, Known Flow Loading, Structure Headlosses, Boundary
Conditions, Design Constraints, Initial Settings, Operational, Cost, and User Data. In this example, we
need to set up a different physical alternative for each design trial we want to evaluate. Each physical
alternative will contain different pressure pipe data.
Select Analysis / Scenarios from the pull-down menu to load the Scenario Manager. Click the
Alternatives button on the left side of the Scenario Manager, and select the Physical Properties tab.
In SewerCAD, we create families of alternatives. There are parent alternatives (base alternatives) and there
are child alternatives. A child alternative inherits data from its parent. You can, however, override data
inherited from the parent, making it local to the child.
Currently, there is only one Physical Alternative listed. The Base-Physical alternative contains the
properties for the current undersized force mains. We would like to add a child of the Base-Physical
alternative so we can inherit most of the data but change only the properties that we want to modify.
Click the Add Child button and enter a descriptive name such as "Larger Pressure Pipes" for the new
alternative and click OK.
The Physical Properties Alternative Editor for the new alternative will appear, and contains the data that
was inherited from the parent alternative. Select the Pressure Pipes tab at the top of the dialog. Notice the
legend at the bottom describing the check boxes. It indicates, all of our data is inherited. If you change any
piece of data, the check box will automatically become checked because that record is now local to this
alternative and not inherited from the parent.

Chapter 3 – Quick Start Lessons

47

Set up this design trial by making the changes shown in the Pipe Alternative Data table below. Click Close
to exit the Physical Properties Alternative Editor and return to the Alternatives Manager.

Pipe Alternative Data

FM-1
FM-2
FM-3

Change From:
To:
Diameter (mm) Diameter (mm)
200
300
200
300
200
300

Next, we will add another physical alternative for another design trial. Highlight the Base-Physical
alternative and click the Add Child button. Enter a descriptive name for the new alternative, such as
"Smaller Pump." Click OK to enter the Physical Properties Alternative Editor.
Select the Pump tab. For this trial, we will leave the existing system the same but with a different size
pump. To change the pump curve, click the cell in the Pump Type column, and set it to Standard (3 point).
Click the ellipsis (…) button to edit the pump curve. Change this design alternative by adding the data
shown in the Pump Alternative Data table below and click OK. Click Close to exit the Physical
Properties Alternative Editor and return to the Alternatives Manager.

Pump Alternative Data

Change From:

Shutoff
Design
Max Operating

Head
(m)
22.67
17
0

Discharge
(m 3/min)
0
24
48

To:
Head
(m)
20
15
0

Discharge
(m3/min)
0
19
38

Last, we will add a Physical alternative that combines the first two design trials in the same alternative for a
third design trial. Highlight the "Larger Pressure Pipes" alternative and click the Add Child button. Enter
a name for the new alternative, such as "Larger FM-3." Click OK to enter the Physical Properties
Alternative Editor.
Select the Pressure Pipe tab. This alternative has inherited the new pressure pipe data that we entered in
the "Larger Pressure Pipes" alternative. Change the diameter of FM-3 from 300 mm to 400 mm. Click
Close to exit the Physical Properties Alternative editor and return to the Alternatives Manager.

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Chapter 3 – Quick Start Lessons

You now have four Physical Properties alternatives. The base alternative contains the existing system’s
data, while the other three contain several changes for different design trials. However, the rest of the data
is the same.
Click Close to exit the Alternatives Manager and return to the Scenario Manager. We must now create
the scenarios that will contain the Physical Properties alternatives we just created.
Part 3 - Editing Base Scenarios
You are now in the Scenario Manager. There is always a default Base scenario that is comprised of the
eleven base alternatives, currently listed in the right pane. The left pane of the Scenario Manager contains
a list of the scenarios. Only the Base is available initially, because we have not created any new scenarios.
Alternatives are the building blocks of a scenario. A scenario is a group of the eleven alternatives and all of
the calculation information needed to solve a model.
For our example, if we wish to analyze the three different design trials for the force main portion of our
system, we must create a new scenario for each of the Physical Properties alternatives we created.
The first step in this process is to rename the Base scenario to a more appropriate name and set the correct
calculation options. Select Base Scenario, click the Scenario Management button, and select Rename
from the pull-down menu. The scenario name in the left pane will become editable. Type a descriptive
name for the scenario, such as "Existing System" and press Enter. Next, click the Scenario Management
button and select Edit from the pull-down menu. Select the Calculation tab. Uncheck the Design check
box in the Steady State section of the dialog. Click Close.
Part 4 - Creating Child Scenarios
The last step in setting up our scenarios is to create child scenarios. The new child scenarios will contain
the Physical Properties alternatives created earlier. Highlight the base scenario entitled "Existing System"
and click the Scenario Management button. Select Add / Child Scenario from the pull-down menu.
You will be prompted for a scenario name. Again, the name should be descriptive, such as "Design Trial
#1." Click OK.
Scenarios work in families just like alternatives, except scenarios do not inherit data directly. A scenario is
a group of alternatives, so a child scenario will inherit the parent’s alternatives. To change the new
scenario you need to change one or more of the alternatives.

Chapter 3 – Quick Start Lessons

49

Our new child scenario initially consists of the same alternatives as its parent scenario. We want to set the
Physical Properties alternative to the first alternative we created, "Larger Pressure Pipes." Click the check
box next to Physical Properties to make that alternative local to this scenario. Then, from the list box,
select Larger Pressure Pipes. Click Close.
Next, make sure the base scenario entitled "Existing System" is selected and click Scenario Management /
Add / Child Scenario. Enter "Design Trial #2" into the field and click OK.
Again click the check box next to Physical Properties and select Smaller Pump from the list box. Click
Close when you are done.
To make a third child scenario, highlight the base scenario again and click Scenario Management /
Add/Child Scenario. Enter the scenario name "Design Trial #3" into the field and click OK.
Change the Physical Properties list box to Larger FM-3. Click Close.

Now we have four scenarios. The base scenario is our existing system. Each child scenario contains a
different physical alternative. The first design trial resizes the pressure pipes, the second design trial
resizes the pump, and the third design trial considers a different combination of pipe sizes. Now we need to
calculate them.
Part 5 - Calculate and Compare
We are going to calculate all of the scenarios at the same time using the Batch Run tool. Click the Batch
Run button on the left side of the Scenario Manager. Click Select / All, or select the check box next to
each scenario, and click the Batch button. Click Yes at the prompt to run the batch for four scenarios.
When it has finished computing, click OK.
You can see the results for each scenario by selecting it in the scenario list. Click the Results tab to see the
selected scenario’s results. We can see that each scenario is different, but what exactly is different about
them? We will use the Scenario Comparison tool to find out.
Click the Scenario Comparison button to start the Annotation Comparison Wizard. Select the Existing
System scenario in the first list box and the Design Trial #1 scenario in the second list box, then click
Next.
We will compare the results for pressure junctions and pressure pipes, so click the check box next to the
Pressure Junction and Pressure Pipe and click Next.

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Select Pressure from the first list box under the Attributes column for pressure junction annotation. You
can edit the actual label in the Mask column. Click Next. Select Velocity from the first list box under the
Attributes column for pressure pipe annotations and click Next. Verify that the annotation is correct and
click Finished.
A plan view of the system with annotation displaying the difference between the two scenarios will appear.
The difference between the two is found by subtracting Scenario 1 from Scenario 2. For example, say
Scenario 1 has a total sanitary load of 4,000,000 l/d at a wet well, and Scenario 2, which represents a future
scenario, has a total sanitary load of 4,500,000 l/d at the same wet well. Comparing total sanitary loads for
Scenario 1 and Scenario 2 would result in annotation stating a difference of 500,000 l/d.
You can select different combinations of the four scenarios from the two list boxes and click the Update
button to view the differences between the two. Or, click the Auto Update check box and the differences
will automatically update every time you change the combination of scenarios in the list boxes. If you
would like to learn more about the various results presentation methods available in SewerCAD, see
Lesson 4.
Close the dialogs and save this project before proceeding to Lesson 4.

3.5 Lesson 4 - Presentation of Results
An important feature in all modeling software is the ability to present results clearly. This lesson outlines
several of SewerCAD’s reporting features, including:


Reports - Displays and prints values for any or all elements in the system.



Element Annotation - Dynamically presents the values of user-selected variables on the drawing.



Profiles - Graphically shows how HGL and elevation vary throughout the gravity portions of the
sanitary sewer.



Color Coding - Assigns colors to values for a variable and applies them to the appropriate locations on
the plan view for a quick diagnostic on how the system is working.

Chapter 3 – Quick Start Lessons

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If, at any time during this lesson, the program asks, "Do you wish to reset all calculated results to
N/A?" click NO.
Part 1 - Reports
For this lesson, we will use the system designed in Lesson 3. If you did not complete Lesson 3, you may
also use the file lesson4.swr, or lesson4.dwg in AutoCAD. This file is located in the SWRC / Lesson
directory. After opening the file, select the "Design Trial #2" scenario from the Scenario toolbar. Click
the GO button and run a regular analysis
When the Results dialog appears, notice that the Results report can be saved to a file or printed by using
the buttons in the top left corner. This report displays key properties of each element on a formatted page.
Click Close. The results for the last run can be accessed at any time by clicking the GO button in the
toolbar and clicking the Results tab.
Open the Manhole Editor for MH-1. Click the Report button at the bottom of the dialog and select
Detailed Report from the pull-down menu to view a formatted summary report of manhole MH-1’s
properties.
Every element has a report with the same general format, which includes the name of the calculated
scenario and a series of tables describing the element’s properties and results in detail. You can print this
report or copy it to the clipboard using the buttons at the top of the dialog. The report will print or paste
into a word processor in the exact format seen on the screen.
Click the Close button on the report and click OK to exit the Manhole Editor.
To print the detailed reports for several elements at one time, select Report / Element Details from the
pull-down menus. In the AutoCAD version, the crosshair changes into a pickbox. Using the pickbox,
select elements from the drawing space that you want SewerCAD to report on and right-click to bring up
the list of Detailed Reports. In the Stand-Alone version, the list of elements will appear immediately.
From this dialog you can select multiple elements and print them to a printer. If you wish to select multiple
elements based on some criteria, click the Select… button to go to the Selection Set dialog. Click Cancel
to return to the Detailed Reports dialog. You can click the Print button to print all of the reports for the
selected elements. Click Cancel to exit the dialog.
Select Report / Element Results from the pull-down menu. In the AutoCAD version use the pickbox to
select the elements for which you want a report. Then right click once to bring up the list of Results
Reports. In the Stand-Alone version, the list of Results Reports will appear immediately. From this dialog
you can print or copy/paste the Results Report for any element. The Results Report contains all of the
results calculated for the selected element. Again, if you wish to select a group of elements based on some
criteria, click the Select… button. Click Cancel when you are done.
Select Scenario Summary from the Reports pull-down menus. This report summarizes the alternatives
and options selected in the current scenario. Click Close.
Now select Report / Project Inventory from the pull-down menus. This report will tell you the total
number of each type of element and the total length of pipe in the system. Click Close.
Part 2 - Tabular Reports
Tabular Reports are extremely powerful tools in SewerCAD. These reports are not only good presentation
tools; they are also very helpful in data entry and analysis. When data must be entered for a large number
of elements, clicking each element and entering the data can be very tedious and time consuming. Using
the tabular reports, elements can be changed using the global edit tool, or filtered to display only the
desired elements. Values that are entered into the table will be automatically updated in the model. The
tables can also be customized. Columns can be added or removed, or you can display duplicates of the
same column with different units. The tabular reports can save you an enormous amount of time and effort.

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Chapter 3 – Quick Start Lessons

To open a tabular report, select the Report / Tables from the pull-down menus or click the Tabular
Report

button on the toolbar. Select the Gravity Pipe Report from the list and click OK.

Tabular reports are dynamic tables of input values and calculated results. White columns are input values
and yellow columns are non-editable calculated values. When data is entered into a table directly, the value
in the model will be automatically updated. These tables can be printed or copied into a spreadsheet
program.
Two very powerful features in these tables are Global Edits and Filtering. Suppose we find that the
downstream inverts of all 250 mm pipes needs to be 10 cm higher. It would be tedious to go through and
re-enter every pipe invert elevation, particularly when dealing with a large system. Instead, we will use the
filter tool in this example to filter out the 250 mm pipes, and the global edit tool to add 10 cm of elevation
to just those pipes.
Right-click the Section Size column and choose Filter / Quick Filter from the pop-up menu. We want to
filter to display only the 250 mm pipes. To do so, set the Column field to Section Size, set the Operator
to =, and set the Value field to 250 mm. Click OK.
Now we will use the Global Edit tool to modify all of the rows in the table. Right click the Downstream
Invert Elevation column and select Global Edit. Select Add from the Operation list and enter 0.1 m into
the Global Edit text box. Click OK.
To deactivate the filter, right click anywhere in the dialog and select Filter / Reset from the pop-up menu.
Click Yes to reset the filter.
You may also wish to edit a table to add or remove different columns. This can be done using the Table
Manager. Click the Options button and select Table Manager. Select the Gravity Pipe Report from the
list and click the Table Management button. In the pull-down menu there is also a New option that would
allow you to create your own table. Any tables you add will be saved for use with other projects. For now,
click the Edit option.
Use the [ < ] and [ > ] buttons to add or remove columns from your table. For this example, select Average
Velocity from the left and click the [ > ] button to add it to the list of selected columns. You can adjust the
order of the columns by using the arrows, or by simply dragging and dropping items.

You may also wish to have two columns with the same attribute but with different units. To do this, check
the Allow Duplicate Columns box. Then you can create the same column twice and just change the units.
Click OK when you are done, then click OK in the Table Manager. The new table will have the added
columns.

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53

If you have made multiple columns and wish to apply separate units to the two columns, click the Options
button and select Use Local Units. This option allows the tabular report to have units independent of the
project and local to the table. Without this option switched on, changing the units of pressure from kPa to
psi in the table would change the unit for pressure throughout the project. The Use Local Units option is
ideal for displaying the same variable with multiple units within the same tabular report. Click Yes in the
warning box that appears indicating that you wish to switch to local units. Then change the units on any of
the numeric columns by right-clicking the column and selecting the Properties option. Change the units in
the list box and click OK.
Click Close.
Part 3 - Element Annotation
Click the GO button and rerun the analysis to update the results to reflect the changes in invert elevations.
Select Tools / Element Annotation from the pull-down menu, or click the Annotation
toolbar.

button on the

This will activate the Annotation Wizard. Select the elements you wish to annotate. In this example, we
will add annotation to the manholes and pressure pipes. Select these elements from the list. Click Next.
This dialog allows you to choose the attributes you wish to annotate for the specified element type. The
Attributes column is used for selecting the attribute you would like to annotate. The Mask is a template of
how the annotation will appear on the screen. The %v and %u options are added to display and control the
value and units associated with the attribute. For this example, we will add annotation for the hydraulic
grade line entering and exiting the manhole. In the first row of the attribute column select Ground
Elevation from the list. In the second row of the attribute column select the Sump Elevation option.
Click Next.
Add Pressure Flow and Pressure Pipe Headloss annotations for pressure pipes in the same manner
described above. Click Next.
This is the last dialog of the Annotation Wizard. Check your annotations in the summary. If there are
any errors, click the Back button to go backwards in the wizard and make any necessary changes. Click
Finished.
The drawing will now display all of the annotations. You can try changing the properties of an element and
recalculating. The annotations will update automatically to reflect any changes in the system. You can
also click and drag the annotation to move it. In the AutoCAD version, click the annotation and then click
the grip to move it, or use an AutoCAD command such as Move or Stretch.
Part 4 - Create a Plan and Profile
To create a plan view of the sewer system, select Report / Plan View / Full View from the pull-down
menu. This will create a plan of the entire system regardless of what the screen shows, while the Current
View option will create a plan of exactly what is displayed in the window at that moment.
The Plan View will be put into a separate window that can then be printed or copied to the clipboard. If
you click the Copy button, you can then paste the plan view into a word processor. Click Close.
Another method that can be used to create a plan view in the Stand-Alone version that can be opened in
AutoCAD is to select File / Export / DXF File from the pull-down menu. This will create a .DXF file of
your network that you can import into AutoCAD. In AutoCAD, use plan views as a quick way to develop
simple scaled views of your primary network.
To create a profile view, select Tools / Profiling from the pull-down menu, or click the Profile button
on the toolbar. This will open the Profiles dialog. From this dialog you can create multiple profile
views for a network. For example, we can create two profiles, one from MH-2 to WW-1 and another from
MH-1 to WW-1. Once the views are created you can go back to the Profiles to access and modify them.

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Chapter 3 – Quick Start Lessons

Before creating a profile you can setup a profile template, which allows you to adjust many of the profile
properties such as scale, label orientations, and profile annotations. By doing so, you can you reuse the
same set of standards every time you create a profile, hence eliminating having to redo the same work.
Click the Templates button on the dialog. This will bring up the list of all available profile templates.
Click the Add button and enter "Lessons Template" and click OK.
For the sake of the lesson, we are going to make two simple changes to illustrate the concept, but as you
can see by scrolling through the tabs the range of customization is extensive. Click the Layout tab. In the
Node section click the Leader check box to create a leader line from the node annotations to the nodes that
they are describing.

Click the Drawing tab and change the Axis Labeling to Both. When this option is toggled the elevations
on the Y-axis will be displayed on both sides of the profile. Feel free to play around with the other options,
or adjust the annotations. Click OK to exit the Template dialog. Click OK a second time to return to the
Profiles dialog.
Click the Profile Management button and select Add. In the Label field enter "MH-2 to WW-1," and
click OK to open the Profile Wizard.
In Step-1 you select the elements to be included in the profile. Click the Select From Drawing button.
This will open a plan view of the drawing. Note, that you can still use the zoom tools from the main
toolbar. In this case click P-3 and P-2, so they are both selected. You can tell this when the lines
delineating the pipes become dashed. In the following image the annotations were turned off for the sake
of clarity.

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55

When you have selected the elements right-click the mouse and select done or click the ESC key. You
should see the elements you selected listed in the Elements section. When you are finished click the Next
button.
In Step-2 you can select the template to be applied to the profile. Select, Lessons Template from the pulldown menu and click Next.
This dialog allows you to set the scale for the axes, as well as the direction of the profile. These same
options are accessible through the Options / Profile Options selection in the Profile Window. For this
example, use the default values and click Finished.
The Profile Window will open. You can quickly move the labels to different locations by simply clicking
and dragging them. Use the zoom buttons at the top to zoom in to any portion of the profile. The HGL
depicts all of the flow profiles within the pipe.
You can customize annotations for the elements in the profile. To do so, click the Options button and
select Annotation… Establishing the annotations is exactly the same as setting up annotations for the plan
view. In this case lets add an annotation displaying the ground elevation at the wet well.
Click the Next button until you get to the Wet Well Annotation section. Select Ground Elevation as an
attribute in the blank row, and click finished.

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Chapter 3 – Quick Start Lessons

Once the profile is made, it can be exported as a .DXF file, printed, or copied to the clipboard. To export
the profile as a .DXF file, click the File button and select Export to DXF. In AutoCAD, you can export
profiles to the drawing by selecting File / Export to AutoCAD. These exported profiles do not
automatically update as the model information changes.
Click Close when you are finished.
Part 5 - Color Coding
Select Tools / Color Coding from the pull-down menus, or click the Color Coding button
toolbar.

on the

The Color Coding dialog allows you to set the color coding for links, nodes, or both. We will color code
links only in this example. From the Color Coding choice list, select the Length attribute. You can enter
any range of values for length into the table. Click the Calculate Range button to get the minimum and
maximum values for the variable displayed at the top of the dialog. Or you can click the Initialize button
and the model will update the color coding automatically. Click OK.
We can add a legend to the drawing by clicking the Insert Legend
button and then choosing the
Link Legend option. Click anywhere on the drawing space to place the legend. In AutoCAD, accept the
defaults when prompted about scale and legend.

3.6 Lesson 5 - Running an Extended Period Simulation
SewerCAD has the ability to analyze time-based or extended period simulations (EPS). This lesson
illustrates different aspects of setting-up and running an EPS including:


Developing loading patterns and hydrographs



Calculating the model

Chapter 3 – Quick Start Lessons

57

• Viewing time-based output
For this lesson, we will use the system designed in Lesson 4. If you did not complete Lesson 4, you may
also use the file lesson5.swr, or lesson5.dwg in AutoCAD. This file is located in the SWRC / Lessons
directory. After opening the file, select the "Design Trial #2" scenario from the Scenario toolbar.
If, at any time during this lesson, the program asks, "Do you wish to reset all calculated results to
N/A?" click NO.
Part 1 - Entering and Applying Loading Patterns
Loading patterns are a series of time-based multipliers that are applied to average loads, which describe
how the load varies over time. In this lesson, we are going to create a loading pattern and apply it to the
unit sanitary loads established with the model in an earlier lesson, and to a new Pattern Load.
To create a new loading pattern select Analysis / Patterns from the pull-down menus. Click the Add
button to bring up a new Pattern dialog.
Enter "Lesson 5 Pattern" in the Label field. Then enter 0 as Start Time, and Starting Multiplier of 0.4.
Then fill in the pattern table on the right-hand side of the dialog starting at hour 3.

Loading Pattern Data

Time
(hours)
0
3
6
9
12
15
18
21
24

Multiplier
0.4
0.8
1.2
1.7
1.4
1.2
1.3
0.6
0.4

Notice that the starting and final multipliers at hour 0 and 24 are equal. The program requires this so in the
case you run the simulation longer than 24 hours then the pattern can repeat itself.
Make sure that the format of the pattern is set to Continuous. You can see a graph of the loading pattern
by clicking the Report button and selecting Graph.
To apply this pattern to the various used unit dry weather labels, select Analysis / Pattern Setups from the
pull-down menus. The Pattern Setup Manager works in a similar manner to the Extreme Flow Setup
Manger, as described in Lesson 1. In this case different patterns are applied to unit sanitary loads as
opposed to extreme flow methods. As with extreme flow setups, you can create different pattern setups and
associate them with different scenarios.
Click the Add button to create a new pattern setup. In the Label field enter in "Lesson 5."
In this lesson, for the sake of simplicity, we will apply the same pattern to all the unit loads. To do so, right
click on the Diurnal Pattern column heading and select Global Edit. Select Lesson 5 Pattern from the
drop-down menu and click OK.

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Chapter 3 – Quick Start Lessons

Click OK to exit back to the Pattern Setup Manager. Click OK to exit back to the drawing.
You can also apply loading patterns to base loads set at individual hydraulic elements. To do so, enter the
editor for MH-1, and click the Loading tab. Click the Add button next to the Sanitary (Dry-Weather)
Flow pane. In the Load Definition pull-down menu select Pattern Load - Base Flow & Pattern, and
click OK.
Enter in a Base Load of 2000 l/d, and select Fixed from the Pattern pull-down menu. Click OK to go
back to the manhole editor, and then click OK in the editor dialog.
Part 2 - Entering Hydrographs
SewerCAD also allows you to enter in hydrographs as a sanitary load (at manholes, wet wells, and pressure
junctions), or as inflows and infiltration (at manholes, pressure junctions, wet wells and gravity pipes).
To explain the concept, we will enter in a single hydrograph as a wet-weather load at manhole MH-2.
Enter the manhole editor for manhole MH-2, and click the Loading tab. Click the Add button next to the
Inflow pane.
Select Hydrograph - Flow vs. Time from the Load Definition pull-down menu, and click OK. Enter
"MH-2 Hydrograph" in the Label field. Then fill in the hydrograph with the data in the following table.

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59

Hydrograph Data

Time
(hours)
0
3
6
9
12
15
18
21
24

Discharge
(l/d)
0
2500
4800
7300
19500
7300
4900
2400
0

Click OK to close the Hydrograph dialog, and click OK again to go back to the drawing pane.
Part 3 - Running the Analysis
To run the EPS, click the GO button. In the Scenario dialog change the Calculation Type from Steady
State to Extended Period. Leave the Duration, Hydraulic Time Step, Hydrologic Time Step set to 24,
1.00, and 0.1 respectively. Change the Pattern Setup from the Base Pattern Setup to Lesson 5.
Click the GO button in the dialog. The program will then calculate output, and when the results appear
click the Close button.
Part 4 - Time Based Graphs and Tables
In SewerCAD you have the capability of creating time based graphs and tables for the comparison of
hydrographs at multiple elements within the system.

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Say we would like to compare the hydrographs generated at manholes, MH-1 and MH-2, and see the
combination of the two routed hydrographs as they exits JC-1. To do so, select Report / Hydrograph
Reports.
Under the Scenarios tab make sure "Design Trial #2" is checked. If multiple scenarios are checked you
will see the hydrograph generated for each of the scenarios for the same element. In this case, only check
the one scenario.
Click the Elements tab. If any elements are selected in the drawing pane they will already selected. Make
sure that the three selected elements are: MH-1, MH-2 and JC-1.
When those elements are selected click the OK button to see the plot.

You can also see this information in a tabular format by clicking the Data tab. This will bring up the table.
By clicking the Copy button the information will be copied to the clipboard you will be able to paste it into
other Windows Applications such Microsoft Word or Excel.
Click Close to exit the plot back to the drawing pane.
You can also create other comparison graphs of attributes over time other than flow by selecting Report /
Element Graph from the pull-down menus and then selecting the element type for which to generate a
plot. As an example, select Manhole.
Under the Graph Setup tab select Hydraulic Grade Line Out as the Dependent Variable. Then select
MH-1 and MH-2 under the Elements tab. Make sure that "Design Trial #2" is selected under the
Scenarios tab. Click OK to view the graph. As you can see, the format and functionality is same as has
the hydrograph plot viewed earlier. Click Close to return to the drawing pane.
Part 5 - Animations
SewerCAD’s animation tool is a dramatic, effective way of presenting and analyzing output data.
In this example, we will animate the color-coding on the main drawing pane, and the hydraulic grade line
on the profile plot.

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Before we animate the drawing pane, we need to color code by attribute that varies with time. In this case
color code the links based on Total Flow attribute. Use the same procedure described in Lesson 4.
To animate the drawing pane simply click the VCR-style play button in the Analysis Toolbar. To stop the
animation click the stop button which appeared upon clicking play.
If you wish to change the frame rate - click the down arrow next to the play button, and select Animation
Delay. Increase or decrease the value depending on your preferences. Click OK to exit the dialog.
Profiles can also be animated in the same manner as the drawing pane. Reopen the profile created in
Lesson 4, from MH-2 to the WW-1. Select Tools / Profiling from the pull-down menus. Select the MH-2
to WW-1 profile and click Open. Simply click the play button in the profile window to start the animation
and click it again to stop it.
From these five lessons, you have had a brief introduction to the capabilities of SewerCAD. Feel free to
continue to play with the program. Use this model to explore and become familiar with all of the features.
If you do not know what a button does, just try it.

Notes

Chapter 4 - Starting a SewerCAD Project

63

Chapter 4
Starting a SewerCAD Project
4.1 Overview
This chapter describes how to start a new project and the files that SewerCAD creates to save your
project’s data. At the beginning of a project, you also need to set some global settings (accessed from the
Tools / Options pull-down menu).

4.2 File Management
SewerCAD uses the .SWR extension to store all model input data, including element inputs and alternatives
and scenarios, both for Stand-Alone and AutoCAD modes.
When SewerCAD runs within AutoCAD, two important files are used. The .SWR file is used to hold all
model data, and a .DWG file contains all of the AutoCAD entities. This means that even a complete
AutoCAD drawing corruption (or loss) will not endanger your hydraulic model data. In fact, you can even
regenerate the AutoCAD modeling elements from the .SWR file!
SewerCAD Backup Files
When a .SWR file is overwritten by a save action, a backup file is created with a .SWK extension.
AutoCAD also generates a backup drawing file with a .BAK extension.
SewerCAD Results
SewerCAD calculation results are stored in files with .OUT extensions for the pressure system results, and
.RST extensions for the gravity system results. Since recalculating the scenarios can regenerate these
results, these files do not necessarily need to be included when backing up your important files.

4.2.1

Multiple Sessions
SewerCAD does not support multiple sessions. SewerCAD uses a single document model, and support for
multiple views has not been implemented. Therefore, do not try to open more than one session of
SewerCAD at the same time, as data loss and data corruption may occur.

4.3 Project Management
4.3.1

Project Setup Wizard
The Project Setup Wizard can only be accessed at the start of a new project. All of the options that are
edited from the Wizard, however, can be changed individually from other pull-down menus.

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The Project Setup Wizard assists you in the creation of a new project by stepping you through many of
the project-wide options, allowing you to set up most of your notes and defaults before you even create the
first pipe. The areas covered by this Wizard include:

4.3.2



Project Summary - Includes information about the project, such as the project title, the project
engineer, and general comments.



Project Options - Include information regarding global options, such as the desired friction method
and coordinate system.



Drawing Options - Include information regarding the drawing pane, such as the drawing scale,
annotation multipliers, and background drawing data (for Stand-Alone mode only).



Prototypes - Enable you to set default values for elements, which are used to initialize values for any
new elements that are added to the project.

Project Summary
The Summary dialog provides a way to enter a Project Title, the name of the Project Engineer, and any
significant comments (for example, the project revision history). The Date field defaults to the current day.
To change any portion of the date, click the item to be changed (i.e: month field), then use the up and down
arrows on the keyboard to set the date.
The Project Title and Project Engineer will print in the footer of reports.
To access the Project Summary dialog, select File / Project Summary from the pull-down menus.

4.4 Options
4.4.1

Global Options
The Global Options dialog allows you to customize the following options for this application:


Welcome dialog (Stand-Alone mode only)



Unit System



Enter Key Behavior



Background/Foreground Color (Stand-Alone mode only)



Sticky Tool Palette (Stand-Alone mode only)



Auto Prompting



Right-Click Context Menu (This toggle exists only in AutoCAD R14; the option is automatically On in
AutoCAD 2000)
To access the Global Options tab, select Tools / Options from the pull-down menus.

Welcome Dialog
The Welcome dialog appears when the program is started, and provides easy access to common tasks you
may want to perform when you first start using the program. The following options are available:


Tutorials



Exit Program

Chapter 4 - Starting a SewerCAD Project

65

Unit System
Although individual units can be controlled throughout the program, you may find it useful to change your
entire unit system at once, to either the System International (metric) unit system or the US Customary
(English) system.
When you switch to a different unit system, you will be asked to confirm this action. If you choose Yes, all
data will be displayed in the default units for the selected system.
If the file that you are editing in Stand-Alone mode is already associated with an AutoCAD
drawing, be careful not to change the unit systems or the .DWG and the .SWR files may become
irreversibly out of sync.

Enter Key Behavior
Enter Key Behavior controls which standard the Enter key follows during editing:


CUA Enter Key - With this setting, the Enter key acts as it normally does for Windows applications.
It is conforming to Common User Access (CUA) standards. This means that when you press the
Enter key, it is as though you pressed the default button on the dialog. CUA Enter Key is the
recommended setting.



Tabbing Enter Key - With this setting, the Enter key behaves the same as the Tab key for editable
fields (not buttons). This means that when you press the Enter key, the cursor will move to the next
field in the dialog.

Window Color
You can specify the background and foreground colors of the main graphical window in Stand-Alone
mode. The foreground color is the default color that is applied to all elements symbols, pipes, labels, and
annotations when no color coding is defined. These color settings also apply to the Scenario Comparison
window, but do not apply to the Profile or Graph Plot windows.

Sticky Tools
Sticky Tools are available in Stand-Alone mode. With Sticky Tools disabled, the drawing pane cursor will
return to the Select tool after creating a node or finishing a pipe run. With Sticky Tools enabled, the tool
does not reset to the Select tool, allowing you to continue dropping new elements into the drawing without
reselecting the tool.
The Sticky Tool Palette can be turned on or off to meet your needs and preferences.

Auto Prompting
Auto Prompting allows you to immediately enter data as elements are added to the drawing, without
interrupting the layout process.
When Auto Prompting is active, the Auto Prompting dialog will immediately appear when you add an
element to the drawing. From the Auto Prompting dialog, you can modify the element's default label and
access the remaining input data by clicking the associated Edit button. Auto Prompting can also be toggled
off in this dialog.

Right-Click Context Menu Option (AutoCAD Only)
If the Right-Click Context Menu option is enabled, a right mouse click on a SewerCAD entity in
AutoCAD R14 will activate a pop-up menu for editing or modifying the element. This functionality
emulates the ability that is available in SewerCAD Stand-Alone mode. Right-clicking any other entity in
the drawing will invoke standard AutoCAD right-click behavior.

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Chapter 4 - Starting a SewerCAD Project

In AutoCAD 2000/2000i, this option is always available. Simply select the element in the
AutoCAD drawing and right-click to obtain a pop-up menu, from which you can select Edit.

4.4.2

Project Options
The Project Options dialog allows you to set the following essential information about your project:


Friction Method



Input Modes

• Pipe Length Rounding
To access the Project Options tab, select Tools / Options from the pull-down menus.

Friction Method Theory
The Friction Method option enables you to select the methodology for determining flow resistance and
friction losses during calculations.
Available methodologies include:


Darcy-Weisbach



Hazen -Williams Formula



Kutter's Equation

• Manning’s Formula
If you change the friction method after pipes have been entered into the network, the program will ask if
you want to update the roughness values of those pipes. If you select Yes, the program will assign all pipes
a new roughness that corresponds to the default roughness of the pipe material.

Input Modes
This program supports several input modes to adjust data entry to your style or the needs of a particular
project.


Coordinates - Coordinates can be displayed either as X and Y coordinates, or as Northing and Easting.
Whichever coordinate input mode is chosen, this method will be active everywhere within the
program.



Hydraulic Settings - This choice list lets you set whether values on control conditions will be input in
terms of hydraulic grade or pressure. Regardless of the mode you choose for input, the program will
always display values in both hydraulic grade and pressure.



Wet Well Levels - This choice list lets you set whether wet well operating ranges will be input in
terms of elevations (height above a datum elevation of 0) or levels (height above the wet well's base
elevation).

Navigation
To access the Input Mode options, select Tools / Options from the pull-down menus, and select the
Project Options tab.

Pipe Length Rounding
Pipe length rounding is used to determine the level of precision desired for scaled pipe lengths. Pipe
lengths will automatically be rounded according to the pipe length rounding value.

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For example, consider a pipe with an actual scaled length of 35.8 meters. If the pipe length rounding value
is 1.0 meters, the program will assume the pipe length to be 36.0 meters.
This only affects the value as it appears in elemental editors, FlexTables, and so on. The actual
length of the pipe figure in the drawing pane is not physically adjusted to force the pipe to a
rounded length.
A change to the pipe rounding length is not retroactive. Therefore, it will not affect existing pipes
unless the User Defined Length is toggled off and then on again in the appropriate element
editor.

4.4.3

Drawing Options
The Drawing Options dialog allows you to specify information regarding the graphical display of
elements in the drawing pane, including:


Drawing Scale



Annotation Multipliers



Pipe Text



Background Drawing

• Symbol Visibility
To access the Drawing Options tab, select Tools / Options from the pull-down menus.

Drawing Scale
You can set the scale that you want to use as the finished drawing scale for the plan view output. Drawing
scale is determined based upon engineering judgment and the destination sheet sizes to be used in the final
presentation.
You may choose either schematic or scaled mode to define the horizontal and vertical distance scales.


Schematic - Pipe lengths are not automatically initialized from their lengths in the drawing pane, but
must be manually entered for each pipe.



Scaled - Pipe lengths are determined from the lengths of the pipe elements in the drawing pane.


HOR - Horizontal scale controls the scale of the plan view.



VER - Vertical scale controls the default elevation scale (for use in profiles, for example).

Scaled or schematic mode can be set on a pipe-by-pipe basis. This is useful when scaled mode is preferred,
but an exaggerated scale is needed for layout of detailed piping arrangements.
Whether the drawing is set in scaled or schematic mode automatically reflects the setting of the pipe
prototype. While in schematic mode, Gravity Pipe Prototypes and Pressure Pipe Prototypes can be
assigned a default length. When the drawing mode is scaled, pipe lengths do not need to be initialized from
the prototype. Switching between scaled and schematic in either the Project Options or Pipe Prototype
dialogs has no effect on existing pipes.

Annotation Multipliers
Annotation multipliers allow you to change the size of symbols, labels and annotation text relative to the
drawing scale. There is not a single annotation size that is going to work well with all projects and scales,
so these values should be adjusted based on your judgment and the desired look of the finished drawings.


Symbol Size - The number entered in this field will either increase or decrease the size of your

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Chapter 4 - Starting a SewerCAD Project
symbols by the factor indicated. For example, a multiplier of 2 would result in the symbol size being
doubled. The program selects a default symbol height that corresponds to 4.0 ft (approximately 1.2 m)
in actual-world units, regardless of scale.



Text Height - The text height multiplier increases or decreases the default size of the text associated
with element labeling by the factor indicated. The program automatically selects a default text height
that displays at approximately 2.5 mm (0.1 in) high at the user-defined drawing scale. A scale of 1.0
mm = 0.5 m, for example, results in a text height of approximately 1.25 m. Likewise, a 1 in = 40 ft
scale equates to a text height of around 4.0 ft.



Annotation Height - The annotation height multiplier increases or decreases the default size of the
element annotation by the multiplier indicated. The program automatically selects a default text height
that displays at approximately 2.5 mm (0.1 in) high at the user defined drawing scale. A scale of 1.0
mm = 0.5 m, for example, results in a text height (to scale) of approximately 1.25 m. Likewise, a 1 in
= 40 ft scale equates to a text height of around 4.0 ft.



Pipe Text - Selecting the Align Text with Pipe box aligns the text with pipes. For more information,
see the Element Annotation topic.
In AutoCAD mode if you change the Symbol Size, Text Height, or Annotation Height you will be
prompted with the Text Positioning dialog, which allows you to select one of the following options when
applying the scaling operation.


Maintain current text positions - The current position of all the annotation will be maintained after
the scale is changed.



Reset text to default positions - The annotation will be repositioned to the default position calculated
by the program.
On the Text Positioning dialog there is a check box that is labeled Don't show this dialog again. If you
check this box you will not be prompted with this dialog until you turn it back on using one of the
following commands at the AutoCAD command line.
WTRCScaleChangeOptions - if you are in WaterCAD
STMCScaleChangeOptions - if you are using StormCAD
SWRCScaleChangeOptions - if you are using SewerCAD

Background Drawing (Stand-Alone mode only)
In Stand-Alone mode, a .DXF file may be used as a background image for the drawing pane.


DXF Background Filename - This field enables you to specify a .DXF file to be used as the
background for your project. Enter the drive, directory, and file name, or click the Browse button to
select a file interactively.



Show Background - If the background .DXF file is turned off, it will not be read from a disk or
displayed in the drawing pane. If the background is not turned off, it will be read from a disk and
displayed.



DXF Unit - The .DXF drawing unit conversion is used when importing .DXF background files, and
also when exporting a .DXF file from the project. Note that the value in this field governs the import
behavior for .DXF files saved in scientific, decimal, or fractional units, but not for .DXF files saved in
architectural or engineering units.
.DXF file import behavior is governed by specific factors within the .DXF file. If a file does not import as
you expect, check the options used to generate it carefully. For example, try importing the .DXF back into
the original program or into another program that supports the .DXF format, such as AutoCAD or
MicroStation. If the file does not import into other applications, there may be an invalid or missing header,
invalid elements, or other errors.

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Symbol Visibility
Symbol visibility allows you to customize the drawing by turning specific layers on or off. Each drawing
layer holds a particular type of graphical element, such as labels and annotation. To remove the graphical
elements of a particular layer from the drawing view, simply uncheck the appropriate boxes, which are as
follows:


Show Labels - The label layer holds the labels for all network elements.



Show Graphic Annotations - Graphic annotation includes lines, borders and text (in Stand-Alone
mode only).



Show Element Annotation - Element annotation includes any dynamic annotation that is added to the
project, such as through the Annotation Wizard.



Show Control Symbols - A symbol may be displayed next to pump and valve elements with one or
more controls, as defined in the Controls tab of the element editors.



Show Flow Arrows - Arrows indicating the flow direction may be displayed after calculations have
been run.

4.5 FlexUnits
4.5.1

FlexUnits Overview
FlexUnits (the ability to control units, display precision, etc) are available from almost anywhere within
Haestad Methods’ software, including element dialogs, FlexTables, and the FlexUnits Manager.

4.5.2

Field Options
Most dialogs provide access to FlexUnits to set options such as unit, rounding, and scientific notation for
any field in the dialog.
To set the display options for a unitized attribute:
1. Right-click the field, and select Properties from the pop-up menu. The Set Field Options dialog
will appear.
2. Set the options you want for your units.
3. Click OK to set the options for the field, or Cancel to leave without making changes.
You will be able to change the following characteristics:


Units



Display Precision



Scientific Notation

• Minimum and Maximum Allowable Values
Some attributes do not have theoretical minimum or maximum values, and others may have an acceptable
range governed by calculation restrictions or physical impossibilities. For these attributes, minimum and
maximum allowable values may not be applicable.
You can see the results of your changes in the preview at the top of the dialog.

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4.5.3

Chapter 4 - Starting a SewerCAD Project

Units
Units are the method of measurement displayed for the attribute. To change units, click the choice list, then
click the desired unit. The list is not limited to either SI or US customary units, so you can mix unit
systems within the same project.
FlexUnits are intelligent - the units actually have meaning. When you change units, the displayed value is
converted to the new unit, so the underlying magnitude of the attribute remains the same.
For example, a length of 100.0 feet is not converted to a length of 100.0 m or 100.0 in. It is correctly
converted to 30.49 m or 1200.0 in.
To access set units, right-click the attribute’s field and select Properties from the pop-up menu, or select
FlexUnits from the Tools pull-down menu.

4.5.4

Display Precision
The precision setting can be used to control the number of digits displayed after the decimal point, or the
rounding of numbers.
Number of Digits Displayed After Decimal Point
Enter 0 or a positive number to specify the number of digits after the decimal point.
For example, if the display precision is set to 3, a value of 123.456789 displays as 123.457. This works
the same regardless of whether scientific notation is active.
Rounding
Enter a negative number to specify rounding to the nearest power of 10. (-1) rounds to the nearest 10, (2) rounds to the nearest 100, and so on.
For example, if the display precision is set to (-3), a value of 1,234,567.89 displays as 1,235,000.
Display precision is for numeric formatting only and will not affect calculation accuracy.
To access display precision, right-click the attribute’s field and select Properties from the pop-up menu, or
select FlexUnits from the Tools pull-down menu.

4.5.5

Scientific Notation
Scientific notation displays the number as a real number beginning with an integer or real value, followed
by the letter "e" and an integer (possibly preceded by a sign). Click the field to turn scientific notation on
or off. A check will appear in the box to indicate that this setting is turned on.
Scientific Notation is for numeric formatting only and will not affect calculation accuracy.
To access scientific notation, right-click the attribute’s field and select Properties from the pop-up menu,
or select FlexUnits from the Tools pull-down menu.

4.5.6

Minimum and Maximum Allowed Value
Minimum and maximum values are used to control the allowable range for an attribute, and are used for
validation of user input. For example, some coefficient values might typically range between 0.09 and
0.20. A frequent user input error is to misplace the decimal point when entering a value. If you enter a
number that is less than the minimum allowed value, a warning message will be displayed. This helps
reduce the number of input errors.

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71

You may change this number in cases where you find the default limits too restrictive.
These allowable minimums and maximums are only available for certain parameters.
To access unit minimum and maximum, right-click the attributes field and select Properties from the popup menu, or select FlexUnits from the Tools pull-down menu.

4.5.7

FlexUnits Manager
The FlexUnits Manager allows you to set the parameters for all the units used. The dialog consists of the
following columns:


Attribute Type - Parameter measured by the unit.



Unit - Type of measurement displayed. To change the unit of an attribute type, click the choice list and
click the unit you want. This option also allows you to use both US Customary and SI units in the
same worksheet.



System - Set the system of units. Click the system column for the desired unit, and a button will
appear. Click the button, and set the unit system to US or SI.



Display Precision - Rounding of numbers and number of digits displayed after the decimal point.
Enter a negative number for rounding to the nearest power of 10: (-1) rounds to 10, (-2) rounds to 100,
(-3) rounds to 1000, and so on. Enter a number from 0 to 8 to indicate the number of digits after the
decimal point. This feature works the same whether scientific notation is on or off.



Scientific Notation - Display numbers in scientific notation. Click the field to turn scientific notation
on or off. If it is turned on, a checkmark appears in the box.
The display units can also be changed from several other areas in the program, and any changes
are project-wide. For example, if length is changed from units of feet to meters, all dialogs will
display length in meters. If you change the units in the dialog from meters to yards, the
FlexUnits Manager will indicate that length is in yards.

To access the FlexUnits Manager, select Tools / FlexUnits from the pull-down menus.

4.6 Quick Attribute Selector
Whenever attributes are selected such as when setting up annotations or database connections, you can
select them from organized categories using the Quick Attribute Selector tool.
Simply click the

in the attribute field to bring up the pull-down menu.

From this menu you can either select attributes from the list of available categories, or you can select from
a list of the most frequently used attributes.
If you select Frequently Used / Edit from the pull-down menu, the Select Field Links dialog will appear.
You can then choose all the attributes you would like to appear in the Frequently Used list.

Notes

Chapter 5 – Layout and Editing Tools

73

Chapter 5
Layout and Editing Tools
5.1 Graphical Editor Overview
This chapter describes the various tools that are available to simplify the process of graphically or manually
entering network data. These tools allow you to select elements to perform various graphical or editing
operations, locate particular elements, review the network for potential problems, label or relabel elements,
review your data, or define any new type of data.

5.2 Graphical Editor
5.2.1

Using the Graphical Editor
One of the most powerful features of the graphical editor, both in Stand-Alone and AutoCAD modes, is the
ability to create, move, edit, and delete network elements graphically. With these capabilities, modeling
becomes a simple point and click exercise. The on-line tutorials have step-by-step instructions for
performing common tasks in the graphical editor, and Lesson 1 also offers assistance.

5.2.2

Working with Network Elements Within the Graphical Editor
Most network editing tasks can be performed using only your mouse. The pull-down menus and AutoCAD
command line also offer the ability to perform many of these tasks, but by simply pointing and clicking
with the mouse you will be able to:


Create New Elements



Select Elements



Edit Elements



Move Elements



Delete Elements



Annotate the Drawing
As you place your mouse over each element, a tool-tip is diplayed informing you of the element’s
label and annotations.

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5.2.3

Chapter 5 – Layout and Editing Tools

Creating New Elements
The tool palette contains all of the tools for adding network elements to the drawing. These element tools
include:
Pipe Layout Tool - Pipes connect the other elements to form the sewer network. The pipes are
the conveyance elements that carry flow through the network to its eventual discharge point at an
outlet. The pipe tool creates either gravity pipes (represented by two parallel lines) or pressure
pipes (represented by a single line) depending on the pipe’s location within the sewer network.
Manhole Tool - Manholes are locations where loads enter the gravity portion of the sewer
network.
Junction Chamber Tool - Junction chambers are locations where upstream flows in a gravity
system combine. No loads enter the sewer at these points.
Wet Well Tool - Wet wells represent boundary conditions between pressure and gravity portions
of a SewerCAD network. They serve as collection points for gravity systems, and as a HGL
boundary node for the pressure system. Dry loads can also enter the sewer network at these
locations.
Pump Tool - Pumps are used to add energy to the system to overcome elevation differences and
headlosses.
Pressure Junction Tool - Pressure junctions are connections between two or more pressure
pipes of varying characteristics. Loads may enter a pressure portion of a network through a
pressure junction.
Outlet Tool - Outlets represent ultimate termination points in a sanitary sewer network.
Although the elements can all be inserted individually, the most rapid method of network creation is
through the Pipe Layout tool. The Pipe Layout tool enables you to connect existing nodes with new
pipes, and also allows you to create new nodes as you lay out the pipes.
For example, when the Pipe Layout tool is active, clicking within the drawing pane will insert a node.
Clicking again at another location will insert another node and connect a pipe between them. Use the online tutorials to experience it interactively.

5.2.4

Changing the Pipe Layout Tool to Insert a Different Type of Node
While laying out a network, you may need to change the type of node that the Pipe Layout tool inserts.
This can be done very easily by following the steps outlined below:
With the Pipe Layout tool active, right-click in the drawing pane.
1.

A pop-up menu will appear with a list of available element types.

2.

Select an element type from the pop-up menu.

The cursor appearance will change to reflect the type of node to be inserted.

5.2.5

Morphing Elements
Occasionally, you may find that you need to replace a node with a different type of node. You can make
this change through a process called morphing.
Morphing enables you to change an existing network node type, without having to delete and re-create the
node and all of its connecting links. Information types that are common between the existing and new

Chapter 5 – Layout and Editing Tools

75

elements will be copied into the new element. To morph an existing element into a different type of
element:

5.2.6

1.

Select the new element type from the Tool Palette.

2.

In the drawing pane, place the cursor over the old element and click.

3.

You will be prompted to verify that you want to morph. Answer yes to perform the morph, or
answer no and a new element will be added at the specified location. If you accidentally morph
an element, this action can be undone by selecting Edit / Undo from the pull-down menus.

Splitting Pipes
You may encounter a situation in which you need to add a new node in the middle of an existing pipe. For
example, you may want to insert a new inlet to capture excessive surface flow in StormCAD, a new
junction to represent additional demand in WaterCAD, or a new manhole to maintain maximum access
hole spacing in SewerCAD.
You can split existing pipes simply by inserting a node along the pipe as follows:
From the Tool Palette, select the node type.
1.

In the drawing pane, place the cursor over the pipe and click

2.

You will be prompted to confirm that you wish to split the pipe. If you choose to split the pipe,
the node will be inserted and two new pipes will be created with the same characteristics as the
original pipe (lengths are split proportionally).

3.

If you choose not to split the pipe, the new element will be placed on top of the pipe without
connecting to anything.
If you accidentally split a pipe, this action can be undone by selecting Edit / Undo from the pull-down
menus.

5.2.7

Selecting Elements
You can select one element or a group of elements from drawing pane on which to perform various
operations such as moving, deleting, and editing.

Selecting Elements (Stand-Alone Mode)
1.

In Stand-Alone model activate the Select tool

.

2.

To select a single element, simply click the desired element. To select a group of elements, click
the drawing pane and drag the mouse to form a selection box around the elements you want to
select, then click again to choose the other corner of the selection box. All elements that are fully
enclosed within the selection box will be selected.
To toggle the selected status of one or more elements, you can follow the same instructions as above while
holding down the Shift key. There are also additional ways to select elements through the Edit menu.
When an element is selected in the Stand-Alone drawing pane, it will be displayed with at least one grip. A
grip is a black box, as shown below, that indicates the figure’s insertion point. The label of a selected item,
or the number of selected items, will be displayed in the status bar.

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Chapter 5 – Layout and Editing Tools

Selecting Elements (AutoCAD Mode)
Within AutoCAD, the Select tool does not need to be active when making a selection. Simply use the
standard AutoCAD selection techniques.
AutoCAD also offers a variety of other selection methods that are outlined in the AutoCAD documentation.
When an element is selected in AutoCAD, it may be displayed in a dashed linetype, and the grips may
become visible, as shown below. The exact display depends on how the element was selected and the
value of the AutoCAD variable GRIPS.

Selecting Upstream / Downstream Elements
You can select all the elements upstream or downstream of a selected gravity node by right clicking on the
node and selecting Select / Elements Upstream / Downstream from … from the pop-up menu. If in
AutoCAD, make sure that Right Click Context Menu is checked in the Global Options dialog.

5.2.8

Editing Elements
There are several methods for editing network element data, including Database Connections, FlexTables,
and the Alternative Manager.
Perhaps the most common method of changing element data, however, is from an individual element’s
editor dialog. To edit a single element, use the Select tool in Stand-Alone mode or in AutoCAD mode.
In Stand-Alone mode and in AutoCAD 2000i, editing a single element is very easy. Simply double-click
the element, and the Editor dialog will open. Alternatively, you can right-click the element and select
Edit… from the pop-up menu.

In AutoCAD 2000 and AutoCAD R14, the process is slightly different. First, click the Select tool, then
click the element you wish to edit. If you are using AutoCAD 2000, or you are using AutoCAD R14 and
you have Right Click Context Menu checked in the Global Options dialog, you can also right-click to
activate the pop-up context menu.
Right-click context menus can provide easy access to common functions and actions.
In AutoCAD 2000i, like in Stand-Alone, you can also double-click the element to bring up its editor.

5.2.9

Moving Elements
You can change the location of elements easily, whether you are in Stand-Alone or AutoCAD mode.
The first step is to select the element(s) to be moved. Next, click to drag the element, and release to drop it
at its new location. In AutoCAD mode, you can accomplish this by dragging the grips. When a node is
moved to a new location, all connected pipes will remain attached, and pipe lengths will automatically
update (unless the pipe has a user-defined length or you are working in schematic mode).

Chapter 5 – Layout and Editing Tools

77

In AutoCAD, this command is the equivalent of the STRETCH command, not the MOVE
command. There are also several other methods of moving items within AutoCAD. For more
information regarding moving elements within AutoCAD, please refer to your Autodesk
documentation.
In the same fashion, you can graphically change the location of element labels and annotation relative to
the element.
A node element can also be moved by editing its coordinates in the element’s editor, in FlexTables, or
through database connections.

5.2.10

Deleting Elements
Deleting elements is quite easy. Simply select the element(s) to be deleted, and press the Delete key on the
keyboard. Note that the integrity of the network is automatically maintained when deletions are performed.
This means that when a node is deleted, any connecting pipes are also deleted to prevent "dangling" pipes
that would cause the network to be invalid.
There are also several other methods of deleting elements, including selecting Edit / Delete from the pulldown menus, or typing ERASE at AutoCAD’s command line.

5.2.11

Other Tools
Although this product is primarily a modeling application, some additional drafting tools can be helpful for
intermediate calculations and drawing annotation. AutoCAD, of course, provides a tremendous number of
drafting tools.
In Stand-Alone mode, drafting and annotation tools allow you to add polylines
(multi-segmented lines), rectangles, and text to the drawing pane.

Line-Enclosed Area
In Stand-Alone mode, you can calculate the enclosed area of any closed polyline. This feature can be
especially helpful for determining the size of storm catchments or land-use areas.
Simply right-click the closed polyline, and select Enclosed Area from the pop-up menu. The Area dialog
will open, displaying the calculated area of the polyline enclosure.
This tool is only available for closed polylines. To close an open-ended polyline, right-click it and
select Close from the pop-up menu.
Although this feature is not provided in AutoCAD mode, you can determine the area of any AutoCAD
polyline by performing a LIST command.

5.3 Selection Sets
Selection sets are user-defined groups of network elements. They allow you to predefine a group of
network elements that you want to manipulate together. Selection sets are defined through the Selection
Set Manager by selecting Tools / Selection Sets from the pull-down menus.

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5.3.1

5.3.2

Chapter 5 – Layout and Editing Tools

Selection Set Manager


Add - Add a new selection set.



Edit - Edit an existing selection set.



Duplicate - Copy an existing selection set.



Delete - Delete an existing selection set.



Rename - Rename an existing selection set.



Notes - Add a note regarding the selection set.

New Selection Set
After clicking Add in the Selection Set Manager, a dialog appears. Simply enter the name of your new
selection set in the dialog. Click OK to name the selection set, or Cancel to exit the dialog without
creating a selection set.

5.3.3

Selection Set Dialog
In this dialog, you will notice two panes. A listing of all the elements in the network is displayed in the
Available Items pane. To add items to the Selected Items pane, select the desired elements in the
available list and click the [>] button under Add. To add all the elements to your selection set, click the
[>>] button.
Additionally, you can use the Select button to highlight items in the Available Items pane using a variety
of powerful selection techniques, or by graphically selecting elements from the drawing. It will also allow
you to invert the selection set, thereby unselecting the ones already selected and selecting the ones not
already selected. You can also clear the selected items using the Select button.
The features mentioned above are also available to remove items from the Selected Items pane.

5.3.4

Duplicate Selection Set
Click Duplicate make a copy of the highlighted selection set.

5.3.5

Delete Selection Set
Click Delete to delete the highlighted selection set.

5.3.6

Rename Selection Set
Click Rename to open a dialog that allows you to change the name of the highlighted selection set.

5.3.7

Selection Set Notes
Click Notes to input free form paragraph text that will be associated with the highlighted selection set.

5.4 Find Element
This is a powerful feature that allows you to quickly locate any element in the drawing by its label. It
performs a case insensitive search. The Find Element feature is available from the Edit menu on the main
window.

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To find an element:
Choose Edit / Find Element from the pull-down menus.
1.

Type the label of the element you wish to find, or click the list box to choose from a sorted list of
elements in the system.

2.

You may wish to choose a Zoom Factor from the list provided. 100% is the default Zoom Factor.
If you wish to magnify the view of the drawing, then choose a Zoom Factor greater than 100%.
To decrease the view of the drawing, choose a Zoom Factor less than 100%.

3.

Click OK.

5.5 Zooming
Zooming controls how large or small a drawing appears on the screen. Zooming is helpful when you want
to enlarge the display to see the drawing’s details, or to reduce the display to see an entire drawing.
Zooming does not change the actual size of the drawing, only the size of the current view.
You can zoom by doing one of the following:
From the View pull-down menu or the toolbars you can perform the following zoom operations:

Zoom In

Enlarge the view of the drawing.

Zoom Out

Decrease the view of the drawing.

Zoom Window

Choose the portion of the drawing to fit in
the window by drawing a selection box
around it.

Zoom Extents

Bring all elements in the drawing into view.

Zoom Previous

Return to the most recent view of the
drawing.

Zoom Center

Center the location of specific coordinates
within the drawing pane.

You can use the Plus key (+) and the Minus key (-) on the numeric keyboard as a shortcut for
zooming in and out respectively (Stand-Alone mode only).
You can also zoom in and out by holding down the ctrl key and using the mouse wheel.

5.5.1

Zoom Center
The Zoom Center dialog provides you with a quick way to zoom to any area of your drawing. This feature
is useful if you want to start laying out a network around certain coordinates, or if you know the
coordinates of an existing element that you would like to locate.
To use Zoom Center:
1.

Select View / Zoom Center from the pull-down menus.

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Chapter 5 – Layout and Editing Tools
2.

In the Zoom Center dialog, enter the coordinates to which you would like to zoom.

3.

Select a zoom factor if you would like to increase or decrease the magnification.

4.

Click OK, and the specified coordinates will be located at the center of the drawing.

Aerial View
The Aerial View is a small navigation window that provides a graphical overview of your entire drawing.
You can toggle the Aerial View window on or off by selecting View / Aerial View from the pull-down
menu.
A Navigation Rectangle is displayed in the Aerial View window. This Navigation Rectangle provides a
"you are here" indicator showing you current zoom location with respect to the overall drawing. As you
pan and zoom around the drawing, the Navigation Rectangle will automatically update to reflect your
current location.
You can also use the Aerial View window to navigate around your drawing. To pan, simply click the
Navigation Rectangle to drag it to a new location. To zoom, click anywhere in the window to specify the
first corner of the Navigation Rectangle, and click again to specify the second corner.
In AutoCAD mode:
Refer to the AutoCAD on-line Help for a detailed explanation.
In Stand-Alone mode:
With Aerial View window enabled (by selecting the View / Aerial View from the pull-down menu), click
and drag to draw a rectangular view box in the aerial view. The area inside this view box is displayed in
the main drawing window. Alternately, any zooming or panning action performed directly in the main
window updates the size and location of the view box in the Aerial View window.
The Aerial View window contains the following buttons:


Zoom Extents - Display the entire drawing in the Aerial View window.



Zoom In - Decrease the area displayed in the Aerial View window.

• Zoom Out - Increase the area displayed in the Aerial View window.
To resize the view box directly from the Aerial View window, simply draw a new rectangular view box.
To change the location of the view box directly in the Aerial View window, you can either drag the view
box frame or create a new one.

5.6 Drawing Review
The Drawing Review window allows you to quickly navigate to and review any group of elements. This
tool is particularly useful for finding potential problems in a network. These problems may result from
data entry errors or data discrepancies in the source (database, Shapefile, or CAD drawing) from which a
model was imported.
By default, when the Drawing Review window opens, all elements will appear in the list. You can work
with any subset of elements by choosing one of the following items:


Select / Custom - Allows you to choose any set of elements to review using the Selection Set dialog.



Select / All Elements - Automatically selects all available elements.



Select / Nodes in Close Proximity - Allows you to select all nodes that are within a user-defined
tolerance of another node. The tolerance is defined in the Nodes in Close Proximity dialog, which
opens when this option is selected. This tool is useful for finding and correcting connectivity problems.

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For example, if two nodes are close too each other the may actually be the same node, and one of them
needs to be deleted.


Select / Pipe-Split Candidates - Allows you to find nodes that are closer to a pipe than a user-defined
tolerance, but are not connected to the system. The tolerance is defined in the Pipe-Split Candidates
dialog, which opens when this option is selected. This option is useful for finding and correcting
connectivity problems.



Select / Orphaned Nodes - Allows you to select all orphaned nodes in your network. A node is an
orphan when it is not connected to any pipe.



Select / Elements with Messages - Allows you to select all the elements that have warnings or error
messages, appearing in the Messages tab of an Element Editor dialog. This is useful for correcting
data entry errors.



Select / Clear Drawing Review Messages - Allows you to reset Drawing Review messages for all
elements in the list. Drawing Review messages are automatically added during various Import
operations such as Polyline to Pipe Import and Land Development Desktop Import (SewerCAD or
StormCAD only). After you review and fix these problems, you may want to clear the review
messages. If you want to retain some of the drawing review messages, simply remove those elements
from the list prior to performing this operation.
The elements you select will appear in the primary list located along the left side of the Drawing Review
window.


Go To - To navigate to an element, select the desired element in the list and press the Go To button.



Next / Prev - To navigate to the elements sequentially, use the Next or Prev buttons.



Zoom - You can control the degree to which the drawing review zooms into the selected element by
choosing a zoom factor from the field labeled Zoom, located in the lower right corner of the dialog.
You can double-click an element in the list to quickly navigate to that element.
If you know the name of the element to which you wish to navigate, type the label in the field
located above the element list and click the Go To button.
All menus and toolbars will remain available even when the Drawing Review window is open.
This allows you to navigate to and fix any problems that you find.

Use the Drawing Review window in conjunction with the QuickView window to review the data for the
selected elements.
To access the Drawing Review dialog, select Edit / Review Drawing from the pull-down menus.

5.6.1

Selection Tolerance
Some select operations require you to specify a tolerance for defining which nodes will be selected for the
Drawing Review window.


Elements in Close proximity - If the distance between the elements in the drawing is within the
specified tolerance, those elements will be selected for display in the Drawing Review window.



Pipe Split Candidates - If the distance between a node and a pipe is within the specified tolerance, it
will be selected for display in the Drawing Review window.

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Chapter 5 – Layout and Editing Tools

5.7 Relabel Elements
Element relabeling allows you to modify the labels of a selected set of elements. This feature is especially
useful with a model built from a database that uses numeric IDs to identify elements, making it difficult to
distinguish between the different types of elements in the system. With element relabeling, you can
quickly append a prefix such as ‘P-’ to all pipes in your system so that it is obvious which labels belong to
elements representing pipes.
The Relabel Elements dialog contains two sections:


Relabel Operations - Allows you to select and define the operations you want to perform.

• Elements Selected - Allows you to select which elements in your project you want to relabel.
To access the Relabel Elements dialog, select Tools/Relabel Elements from the pull-down menu.

5.7.1

Relabel Operations
The element relabeling tool allows you to perform three types of operations on a set of element labels:
Replace, Renumber, and Append. The active relabel operation is chosen from the list box in the Relabel
Operations section of the Relabel Elements dialog. The entry fields for entering the information
appropriate for the active relabel operation appear below the Relabel Operations section. The following
list presents a description of the available element relabel operations.


Replace - This operation allows you to replace all instances of a character or series of characters in the
selected element labels with another piece of text. For instance, if you selected elements with labels P1, P-2, P-12, and J-5, you could replace all the P's with the word Pipe by entering ‘P’ in the Find field,
‘Pipe’ in the Replace With field, and clicking the Apply button. The resulting labels are Pipe-1, Pipe2, Pipe-12, and J-5. You can also use this operation to delete portions of a label. Suppose you now
want to go back to the original labels. You can enter ‘ipe’ in the Find field and leave the Replace
With field blank to reproduce the labels P-1, P-2, P-12, and J-5. There is also the option to match the
case of the characters when searching for the characters to replace. This option can be activated by
checking the box next to the Match Case field.



Renumber - This operation allows you to generate a new label, including suffix, prefix, and ID
number for each selected element. For example, if you had the labels P-1, P-4, P-10, and Pipe-12, you
could use this feature to renumber the elements in increments of five, starting at five, with a minimum
number of two digits for the ID number field. You could specify a prefix ‘P-’ and a suffix ‘-Z1’ in the
Prefix and Suffix fields, respectively. The prefix and suffix are appended to the front and back of the
automatically generated ID number. The value of the new ID for the first element to be relabeled, 5, is
entered in the Next field. The value by which the numeric base of each consecutive element is
incremented, 5, is entered in the Increment field. The minimum number of digits in the ID number, 2,
is entered in the Digits field. If the number of digits in the ID number is less then this value, zeros are
placed in front of it. Click the Apply button to produce the following labels: P-05-Z1, P-10-Z1, P-15Z1, and P-20-Z1.



Append - This operation allows you to append a prefix, suffix, or both to the selected element labels.
Suppose that you have selected the labels 5, 10, 15, and 20, and you wish to signify that these elements
are actually pipes in Zone 1 of your system. You can use the append operation to add an appropriate
prefix and suffix, such as ‘P-’ and ‘-Z1’, by specifying these values in the Prefix and Suffix fields and
clicking the Apply button. Performing this operation yields the labels P-5-Z1, P-10-Z1, P-15-Z1 and
P-20-Z1. You can append only a prefix or suffix by leaving the other entry field empty. However, for
the operation to be valid, one of the entry fields must be filled in.
The selection set of elements on which the relabel operation is to be performed can be selected in the
Elements section of the Relabel Elements dialog.
To access the Relabel Elements dialog, select Tools / Relabel Elements from the pull-down menus.

Chapter 5 – Layout and Editing Tools

5.7.2

83

Elements Selected
The Elements section contains a pane that lists the elements to be relabeled. You can select the set of
elements that appears in this pane by clicking the Select button. This accesses the Selection Set dialog,
where you can pick a set of elements from all the elements currently in the project.
For the Append and Replace operations, the order that the elements appear in the text pane does not affect
the results of the operation. However, for the Renumber operation, the order in which the elements appear
in the text pane determines the order in which they will be renumbered. The default order in which the
elements appear in the text pane is in the alphanumeric order of the element labels, called Ascending order.
If you wish to change this order, click the Sort button, and select Network Order to put the elements in
the order they appear in the network, Descending Order to put them in reverse alphanumeric order, or
Ascending Order to put them back in alphanumeric order.

5.8 Element Labeling
The Element Labeling dialog is used to specify the automatic numbering format of new elements as they
are added to the network. The following options are available:


Element - View the type of element to which the label applies.



Next - Enter the integer you want to use as the starting value for the ID number portion of the label.
The program will generate labels beginning with this number, and will choose the first available
unique label.



Increment - Enter the integer that will be added to the ID number after each element is created to yield
the number for the next element.



Prefix - Enter the letters or numbers that will appear in front of the ID number for the elements in your
network.



Digits - Enter the minimum number of digits that the ID number will have. For instance, 1, 10, and
100 with a digit setting of two would be 01, 10, and 100.



Suffix - Enter the letters or numbers that will appear after the ID number for the elements in your
network.



Preview - View an example of what the label will look like based on the information you have entered
in the previous fields.
Changes to the element labeling specifications will only affect the numbering of new elements. Existing
elements will not be affected. In order to adjust the numbering of existing elements, utilize the Relabel
Elements option accessible from the Tools menu.
Pipe labeling can be aligned with the pipes or be displayed horizontally, depending on the Pipe
Text setting specified in the Drawing Options dialog.
You can control the angle at which the text flips from one side of the pipe to the other to read in the
opposite direction, when the pipe direction on a plot is nearly vertical. By default, the text flips direction
when the pipe direction is 1.5 degrees, measured counter-clockwise from the vertical. You may modify
this value by inserting a TextFlipAngle variable in the Haestad.ini file that is located in the program file of
your Haestad directory, and specifying the angle at which the text should flip. The angle is measured in
degrees, counter-clockwise from the vertical. For instance, if you want the text to flip when the pipe
direction is vertical, you should add the following line to the Haestad.ini file:

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TextFlipAngle=0.0
Reasonable values typically fall in the range 15.0 deg to -15.0 deg.
To access the Element Labeling dialog, select Tools / Element Labeling from the pull-down menus.

5.9 Quick View
The Quick View window provides you with a fast way to edit or view the data associated with any element
in the network without having to open the element dialog. It is a floating window that includes input and
output information for any element that you have selected. It also includes a convenient color-coding
legend. Three tabs are provided on the window:


Input - Contains input data for the selected element.



Output - Contains output data for the selected element.

• Legend - Displays ranges of the active color-coding.
When the Quick View window is open, the data for an entity will immediately be displayed when you
select it within the graphical editor. Once an element has been selected, click on any editable field on the
Input tab to edit the associated value. Edits will be committed when you leave the Quick View window.
Changes made through the Quick View window can be undone/redone by accessing the Edit menu.
You can change the size of the Label, Value, and Unit columns on the Input/Output tabs by using
the resizing bar at the top of the Quick View window.
You can highlight an Input or Output attribute (e.g. Demand), by clicking the label of that
attribute in the Quick View window. This highlighting provides for better visual feedback, for
example, when monitoring the pressures at several nodes.

The Quick View window can be accessed by clicking the Quick View window button
toolbar. You can also select View / Quick View from the pull-down menus.

on the

Chapter 6 – Hydraulic Element Editors

85

Chapter 6
Hydraulic Element Editors
6.1 Overview
The primary component of a SewerCAD project is the collection system model. A collection system model
may contain multiple independent (not connected) networks in a single project file. Each network may
contain gravity elements, and pressure elements, in which the flow is under pressure due to the presence of
a pumping station upstream. The element types that are used to form a network are:


Manholes - These are node elements used to model access hole structures. At a manhole, you can
enter a local load and also model the headloss associated with the structure.



Junction Chambers - These are node elements used to model underground structures. Unlike a
manhole, no local load can be entered at a junction chamber; however, junction headloss associated
with this structure can be modeled.



Wet Wells - These are storage nodes typically used in conjunction with one or more pumps to model a
pumping station. Wet wells can be defined with either a constant section area or variable section area.
A local loading may also be added at a wet well.



Pumps - Pumps are elements that add head to the system as water passes through them. A pump is
typically defined by a pump curve and control elevations, at which the pump turns off or on.



Pressure Junctions - These are node elements used to model a junction under pressure at the
downstream end of one or several pressure pipes.



Outlets - These are node elements that define the "root," or most downstream element of a SewerCAD
network. They specify the starting hydraulic grade line for the backwater analysis. Gravity networks
contain only one outlet element. However, a pump may pump into more than one forcemain, thus
allowing split flow and possibly more than one outlet in pressure networks.



Gravity Pipes - These are link elements of constant shape, material, size, and slope that are used to
transport the discharges from node to node.



Pressure Pipes - These are link elements of circular shape and of constant material and size used to
transport the discharges under pressure from node to node.
This chapter presents a detailed look at the input and output data used in a SewerCAD project, and the way
it is organized in the graphical user interface. First, a description of the elements used to model the sewer
collection system is provided. Second, the various means of entering loading data are described. Then,
prototypes are discussed as a way to initialize new model elements with default values. Finally, the user’s
ability to augment SewerCAD’s existing attribute set with User-Data extensions are discussed.
A collection system model will not be considered valid for calculation if the number of pipes
exceeds the licensed size. To determine how many pipes you are licensed for, select the Help /
About SewerCAD from the pull-down menu. Click the Registration button. A single SewerCAD
project file can contain any number of valid networks, but if the total number of pipes exceeds
the licensed size, the project will not calculate.

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Chapter 6 – Hydraulic Element Editors

6.2 Element Editors
6.2.1

Using Element Editors
The Element Editors allow you to edit all input data and view all output data defining a single network
element.
Element data may also be viewed/edited more efficiently through FlexTables, which display all
the data in customizable tabular format, allowing you to perform functions such as sorting,
filtering, and global editing. The data may also be quickly reviewed through the Quick View
window.
You can move to connecting elements from the selected element’s editor by using the following buttons.
Click this button to move to the default upstream element of the selected gravity element or to the
default-connected element of the selected pressure element.
Click this button to move to the default downstream element of the selected gravity element.
Click the side-triangle button to open a pop-up menu to select one of the available connecting elements.
To access an Element Editor:

6.2.2

Stand-Alone:

Double-click the element you wish to edit, or right-click the element and select
Edit from the drop-down menu.

AutoCAD R14:

Pick the Select tool and click the element you wish to edit. If the Right-Click
Context Menu option is enabled, you can also right-click the element and select
Edit from the drop-down menu.

AutoCAD 2000:

Pick the Select tool and click the element you wish to edit, or select the element
and choose Edit from the drop-down menu.

AutoCAD 2000i:

Double-click the element you wish to edit, or right-click the element and select
Edit from the drop-down menu.

Manholes
Manholes are the elements used to model the access holes in a sewer collection system. The Manhole
Editor organizes the related input data and calculated results into the following tabs:


General - General manhole information containing geographical data and hydraulic results.



Headlosses - Headloss calculation method and parameters.



Diversion - Diversion target, rating table, and results.



Loading - Loading data, which is composed of sanitary loads, wet weather loads, and known flows.



Design - Constraints used during automatic design.



Cost - Cost analysis input/output data used when performing cost analysis calculations.



User Data - Additional user-entered data. For instance, you can add new fields such as the manhole
installation date.



Messages - Calculation messages, such as computation warnings or error messages, and user-entered
notes and descriptions.
For further details, refer to the topics describing each tab.

Chapter 6 – Hydraulic Element Editors

6.2.3

87

Junction Chambers
Junction chambers are used to model underground nodal structures in gravity sewer collection systems.
Unlike a manhole, no local load can be entered at a junction chamber. Headloss associated with junction
chambers can also be modeled. The Junction Chamber Editor organizes the related input data and
calculated results into the following tabs:

6.2.4



General - General junction chamber information containing geographical data and hydraulic results.



Headlosses - Headloss calculation method and parameters.



Diversion - Diversion target, rating table, and results.



Design - Constraints used during automatic design.



Cost - Cost analysis input/output data used when performing cost analysis calculations.



User Data - Additional user-entered data. For instance, you can add new fields such as the junction
installation date.



Messages - Calculation messages, such as computation warnings or error messages, and user-entered
notes and descriptions.

Wet Wells
Wet wells are used to model the storage structures in sewer collection systems. They are storage nodes
usually used in conjunction with one or several pumps to model a pumping station. Wet wells can be
defined with either a constant section area or a variable section area. A local loading may also be added at
a wet well. The Wet Well Editor organizes the related input data and calculated results into the following
tabs:

6.2.5



General - General wet well information containing geographical data and hydraulic results.



Section - Geometric characteristics of the well, as well as water level limits.



Loading - Load data, which is composed of sanitary loads, wet weather loads, and known flows.



Cost - Cost analysis input/output data used when performing cost analysis calculations.



User Data - Additional user-entered data. For instance, you can add new fields such as the well
construction date.



Messages - Calculation messages, such as computation warnings or error messages, and user-entered
notes and descriptions.

Pumps
Pumps are used to model devices that add energy to sewer systems as water passes through them. A pump
is typically defined by a pump curve and control elevations, at which the pump turns off or on. A pump is
conceptually a composite element, modeled as a link with junction nodes on either end, although it is
represented in the graphical editor by a single icon. The Pump Editor organizes the related input data and
calculated results into the following tabs:


General - General pump information containing geographical data, the pump curve data, the initial
setting, and the hydraulic results.



Controls - Data specifying the on/off elevation settings of the pump, as well as relative speed factor
settings in the case of a variable speed pump.



Cost - Cost analysis input/output data used when performing cost analysis calculations.



User Data - Additional user-entered data. For instance, you can add new fields such as the pump
installation date.

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6.2.6

Chapter 6 – Hydraulic Element Editors
Messages - Calculation messages, such as computation warnings or error messages, and user-entered
notes and descriptions.

Pressure Junctions
Junction structures are used to model junctions under pressure at the downstream end of one or several
pressure pipes. The Pressure Junction Editor organizes the related input data and calculated results into
the following tabs:

6.2.7



General - General manhole information containing geographical data and hydraulic results.



Loading - Load data, which is composed of sanitary loads, wet weather loads, and known flows.



Cost - Cost analysis input/output data used when performing cost analysis calculations.



User Data - Additional user-entered data. For instance, you can add new fields such as an observed
pressure at the junction.



Messages - Calculation messages, such as computation warnings or error messages, and user-entered
notes and descriptions.

Outlets
Outlets are the node elements that define the "root," or most downstream element of a SewerCAD network,
and specify the starting hydraulic grade line for the backwater analysis. The Outlet Editor organizes the
related input data and calculated results into the following tabs:

6.2.8



General - General outlet information containing geographical data and hydraulic results.



Design - Constraints used during automatic design.



Cost - Cost analysis input/output data used when performing cost analysis calculations.



User Data - Additional user-entered data. For instance, you can add new fields such as the outlet
installation date.



Messages - Calculation messages, such as computation warnings or error messages, and user-entered
notes and descriptions.

Gravity Pipes
Gravity pipes are used to model the pipes in the system in which the flow is discharging downstream due to
gravity. The Gravity Pipe Editor organizes the related input data and calculated results into the following
tabs:


General - General pipe information containing physical characteristics data and hydraulic results.



Profile - Information regarding the pipe’s physical and hydraulic profile.



Design - Constraints used during automatic design.



Infiltration - Infiltration data, which may be proportional to the pipe characteristics or defined as a
lump sum.



Cost - Cost analysis input/output data used when performing cost analysis calculations.



User Data - Additional user-entered data. For instance, you can add new fields such as the pipe
installation date.



Messages - Calculation messages, such as computation warnings or error messages, and user-entered
notes and descriptions.

Chapter 6 – Hydraulic Element Editors

6.2.9

89

Pressure Pipes
Pressure pipes are used to model the pipes carrying flow under pressure, discharging from a pumping
station located upstream in the sewer collection system. The Pressure Pipe Editor organizes the related
input data and calculated results into the following tabs:


General - General pipe information containing dimension and physical characteristics data, and
hydraulic results.



Controls - Control data used to specify whether the pipe is open or closed based on the HGL or
pressure at any given node in the system.



Cost - Cost analysis input/output data used when performing cost analysis calculations.



User Data - Additional user-entered data. For instance, you can add new fields such as the pipe
installation date.



Messages - Calculation messages, such as computation warnings or error messages, and user-entered
notes and descriptions.

6.3 Element Editors' Tabs
6.3.1

General Tab
Manholes, Junction Chambers, and Outlets
General Tab (for Manholes, Junction Chambers, and Outlets)
The General tab for manholes, junction chambers, and outlets is organized into the following sections:


General - General data about the node.



Structure - Geometric and elevation data.



Hydraulic Summary - Hydraulic results for manholes or junction chambers.



Tailwater Hydraulics - Tailwater data for an outlet.

• Flow Summary - Total flow and distribution of the flow at a node.
For further details, refer to the topics describing each section.
General Section
The General section allows you to enter general information about the node, such as:


Label - Unique name by which an element will be referred to in reports, error messages, and tables.



X (Easting) - The location of the node may be represented as an X-value or an Easting value,
depending on individual preferences.



Y (Northing) - The location of the node may be represented as a Y-value or a Northing value,
depending on individual preferences.



Ground Elevation - Elevation of the ground surface at the node.



Station / Calculated Station - Distance along the alignment of pipes. The starting station can be
specified at an outlet or wet well, and is calculated for nodes and junctions.
The Station attribute is only editable for Outlet and Wet Well elements. For all other elements,
the station is computed during a calculation based on the initial station and pipe lengths.

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Chapter 6 – Hydraulic Element Editors

Structure Section
The Structure section allows you to enter data pertaining to the node’s structure:


Bolted Cover - Specify whether a manhole cover is bolted, in which case the flow is contained inside
the structure when the water level rises to the rim elevation, instead of spilling over.



Set Rim to Ground Elevation - This check box enables or disables a data entry shortcut. If the box is
checked, the manhole or outlet rim elevation will be set equal to the ground elevation automatically.
During an automatic design, the structure rim elevations will be the same as the ground elevation.



Rim Elevation - This field is editable only when the Set Rim to Ground Elevation check box for a
manhole or outlet is unchecked.



Sump Elevation - Elevation of the bottom of a manhole or outlet.



Structure Diameter - Cross-sectional diameter of a manhole or junction chamber. This value is used
in hydraulic calculations and profile drawings, but not in plan view.



Top Elevation - Elevation of the top of a junction chamber.



Bottom Elevation - Elevation of the bottom of a junction chamber.
A warning will be posted to the calculation log whenever the defined sump elevation is invalid
(i.e. above any connecting pipe invert).
During automatic design calculations, the program automatically sets sump inverts according to
the design constraints specified in the active Design Constraints Alternative.

Hydraulic Summary Section
The Hydraulic Summary section, available on the General tab of the Manhole and Junction Chamber
Editors, provides the following quick summary of the calculated hydraulic results:


Hydraulic Grade Line In - Hydraulic grade at the downstream end of the incoming pipe section.



Gravity Element Headloss - Headlosses associated with factors such as mixing and change of
direction.



Hydraulic Grade Line Out - Hydraulic grade at the upstream end of the outgoing pipe section.

Tailwater Hydraulics Section
The Tailwater Hydraulics section, available on the General tab of the Outlet Editor, contains the
following fields:


Tailwater Condition - Select the outfall condition (crown, free-outfall, or user-specified) from the
choice list. The program performs a backwater analysis throughout the sewer system starting from the
outfall condition selected.



Tailwater Elevation - Only editable under user-specified tailwater conditions. For all other tailwater
conditions, the field is calculated.



Hydraulic Grade Line Out - The computed tailwater elevation.
You may want to let the program compute an ideal outfall invert elevation and profile as a
preliminary design. To do this, simply run an automatic design and let the program compute a
good estimate based on cover requirements, slope constraints, and pipe sizes.

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Flow Summary Section
This section reports a summary of the total flow at a node and the distribution of this flow.
For Steady State mode the fields displayed are as follows:


Total Dry Weather Flow - Total flow at a node resulting from sewage generated during dry weather
from the network upstream of a given node.



Total Wet Weather Flow - Total flow at a node resulting from the intrusion of rainfall water into the
sewer system from the upstream network. Wet weather load consists of groundwater infiltration and
rainfall inflow. Groundwater infiltration occurs in gravity pipes while inflows occur at manholes and
wet wells.



Pumped Flow - Portion of the total flow that comes from pumps located in the upstream network,
when the Use Pumped Load toggle in the Calculation Options dialog is On. In this case, the flow
coming out of pumps is treated as a fixed flow, to which peaking factors do not apply.



System Known Flow - Portion of the total flow derived from manually entered Known Flows
upstream of the reporting point. Known flows are not additive except at network junctions. The
Known Flow component will remain constant until it encounters a downstream Known Flow of a
different value.

• Total Flow - Total flow going through an element of the network.
For EPS mode the fields displayed are as follows::


Total Flow - Represents the total flow coming to the structure, which includes the upstream flow
through pipes, incoming diverted flow, and the local sanitary loads and inflows.



Diverted Flow - Represents the amount of the total flow, which is diverted from the inlet to the
diversion target.



Flow In - Represents the portion of the flow established locally at the selected node, such as unit dry
weather and wet weather loads.
You can toggle between Steady State and EPS modes by clicking the GO button and changing the
Calculation Type.

Wet Wells
Wet Well General Tab
The General tab for wet wells is organized into the following groups:


General - General data about the node.



Hydraulic Summary - Reports calculated hydraulic grade line leaving the well.

• Flow Summary - Total flow and distribution of the flow at the wet well.
For further details, refer to the topics describing each section.
General Section
The General section allows you to enter general information about the node, such as:


Label - Unique name by which an element will be referred to in reports, error messages, and tables.



X (Easting) - The location of the node may be represented as an X-value or an Easting value,
depending on individual preferences.

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Y (Northing) - The location of the node may be represented as a Y-value or a Northing value,
depending on individual preferences.



Ground Elevation - Elevation of the ground surface at the node.



Station / Calculated Station - Distance along the alignment of pipes. The starting station can be
specified at an outlet or wet well, and is calculated for nodes and junctions.
The Station attribute is only editable for Outlet and Wet Well elements. For all other elements,
the station is computed during a calculation based on the initial station and pipe lengths.

Wet Well Hydraulic Summary Section
This section reports the hydraulic grade line exiting the wet well, and hence the level in the wet well itself.
The summary consists of Hydraulic Grade Line Out, which represents the hydraulic grade in the wet well
calculated as explained in the Hydraulic Transition from Gravity to Pressure Network section in Appendix
B.
Flow Summary Section
This section reports a summary of the total flow at a node and the distribution of this flow.
For Steady State mode the fields displayed are as follows:


Total Dry Weather Flow - Total flow at a node resulting from sewage generated during dry weather
from the network upstream of a given node.



Total Wet Weather Flow - Total flow at a node resulting from the intrusion of rainfall water into the
sewer system from the upstream network. Wet weather load consists of groundwater infiltration and
rainfall inflow. Groundwater infiltration occurs in gravity pipes while inflows occur at manholes and
wet wells.



Pumped Flow - Portion of the total flow that comes from pumps located in the upstream network,
when the Use Pumped Load toggle in the Calculation Options dialog is On. In this case, the flow
coming out of pumps is treated as a fixed flow, to which peaking factors do not apply.



System Known Flow - Portion of the total flow derived from manually entered Known Flows
upstream of the reporting point. Known flows are not additive except at network junctions. The
Known Flow component will remain constant until it encounters a downstream Known Flow of a
different value.

• Total Flow - Total flow going through an element of the network.
For EPS mode the fields displayed are as follows::


Total Flow - Represents the total flow coming to the structure, which includes the upstream flow
through pipes, incoming diverted flow, and the local sanitary loads and inflows.



Diverted Flow - Represents the amount of the total flow, which is diverted from the inlet to the
diversion target.



Flow In - Represents the portion of the flow established locally at the selected node, such as unit dry
weather and wet weather loads.
You can toggle between Steady State and EPS modes by clicking the GO button and changing the
Calculation Type.

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Pumps
Pump General Tab
The General tab for pumps is organized into the following groups:


General - General data about the pump.



Pump - Contains the type of pump curve and related data.



Initial Setting - Initial conditions describing the pump's behavior at the start of the analysis.



Pipes - Indicates the direction in which the pump is operating (from upstream node to downstream
node), and lets you reverse the direction of pumping by clicking the Reverse button.



Calculated Hydraulics - Reports the hydraulic grade and pressure at the adjacent end of both
connecting pipes, intake and discharge.



Operating Point - Represents the values for pump head and discharge, which are computed by the
program to balance with the remaining system heads and flow rates.
The Initial Settings are used as the permanent settings. However, they can be overruled by the
presence of controls if the Use Controls in Steady State Analysis check box in the Calculation
Options dialog is checked.

For further details, refer to the topics describing each section.
General Section
This section allows you to enter general information about the pump such as:


Label - Unique name referencing the pump in reports, error messages, and tables.



X (Easting) - The location of the pump may be represented by an X-value or an Easting value,
depending on individual preferences.



Y (Northing) - The location of the pump may be represented by a Y-value or a Northing value,
depending on individual preferences.



Elevation - Elevation of the pump.

Pump Section
The information required for a pump depends on the type of pump that is selected. The possible
information is as follows:


Pump Type - Select one of the six available types of pump curves.



Pump Power - Represents the water horsepower, or horsepower that is actually transferred from the
pump to the water. Depending on the pump's efficiency, the actual power consumed (brake
horsepower) may vary.



Shutoff - Point at which the pump will have zero discharge. It is typically the maximum head point on
a pump curve.



Design - Point at which the pump was originally intended to operate. It is typically the best efficiency
point (BEP) of the pump. At discharges above or below this point, the pump is not operating under
optimum conditions.



Max Operating - Highest discharge for which the pump is actually intended to run. At discharges
above this point, the pump may behave unpredictably, or its performance may decline rapidly.

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Max Extended - Absolute maximum discharge at which the pump can operate, adding zero head to
the system. This value may be computed by the program, or entered as a custom extended point.

All defined pump curve points have an associated head and discharge.
Initial Setting Section
The initial conditions for a pump describe the pump's behavior at the start of the analysis. These conditions
include:


Status - One of two available status conditions: On (normal operation), Off (no flow under any
condition).



Relative Speed Factor - Characteristics of the pump relative to the speed for which the pump curve
was entered, in accordance with the affinity laws. A speed factor of 1.00 will indicate pump
characteristics identical to those of the original pump curve.
In Steady-State Analysis mode, the Pump Status is used as the permanent status. However, it can
be overruled by the presence of controls, if the Use Controls in Steady-State Analysis check box
in the Calculation Options dialog is checked. The Calculation Options dialog is accessed by
clicking the GO button in the main view to display the Calculation tab of the Scenario Editor,
and then clicking the Options button.

Pipes Section
This indicates the direction in which the pump is operating (from upstream pipe to downstream pipe).
You can switch the Upstream and Downstream Pipes by clicking the Reverse button.
Calculated Hydraulics Section


Intake Pump Grade - HGL on the suction side of the pump.



Intake Pump Pressure - Pressure on the suction side of the pump.



Discharge Pump Grade - HGL on the downstream side of the pump.



Discharge Pump Pressure - Pressure on the downstream side of the pump.

Operating Point Section
The pump's operating point represents the values for pump head and flow, which are necessary to meet the
discharge load on the pump as well as overcome the system losses.
The calculated parameters are:


Pump Head - Head generated by the pump at the operating point.



Pressure Flow - Flow through the pump.
For a constant power pump, the calculated operating point may be outside the normal operating
range of a realistic pump. Be very cautious and check all results carefully.
For more information about the theory behind the pump operating point, see the help on pump
theory in Appendix B.

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Pressure Junction
Pressure Junction General Tab
The General tab for pressure junctions is organized into the following sections:


General - General information about the junction.

• Hydraulic Results - Calculated hydraulic grade and pressure at the junction.
For further details, refer to the topics describing each section.
General Section
The General section for pressure junctions allows you to enter general information such as:


Label - Unique name by which a pressure junction will be referred to in reports, error messages, and
tables.



X (Easting) - May be presented as an X-value or as an Easting value, depending on individual
preferences.



Y (Northing) - May be presented as a Y-value or a Northing value, depending on individual
preferences.



Elevation - Elevation of the pressure junction.

Hydraulic Results Section
The Hydraulic Results section for pressure junctions reports the following results:


Calculated Hydraulic Grade Pump Hydraulic grade at the junction.



Pressure - The pressure calculated at this junction.

Gravity Pipe
Gravity Pipe General Tab
The General tab for gravity pipes contains all the physical data necessary for successfully modeling pipes.
The tab also provides a brief hydraulic summary of the flow and velocity through the pipe, as well as the
pipe’s constructed slope and full flow capacity. This tab has five sections:


Pipe - General characteristics of the pipe.



Invert Elevations - Upstream and downstream invert elevations.



User Defined Length - Specify whether the pipe length is calculated automatically or user-defined.



User Defined Bend Angle - Specify whether the angle the pipe creates with the downstream pipe is
calculated automatically or user-defined.

• Hydraulic Summary - Displays the computed hydraulic data of the pipe.
For further details, refer to the topics describing each section.
Pipe Section
This section is where all of the pipe general characteristics are entered. The following fields are available:


Label - Unique name by which a pipe will be referred to in reports, error messages, and tables.



Section Shape - Select one of the following pipe section shapes: arch, box, circular, or elliptical
(vertical or horizontal).

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Material - Pipe material with its associated roughness value selected from those available in the
Material Library.



Roughness Coefficient - Specify the coefficient corresponding to the roughness method selected
during the project setup (Manning’s n, Kutter’s n, Hazen-Williams C, or Darcy-Weisbach roughness
height) for the selected material. You can keep the roughness value associated with the selected
material in the Material Library, or override the roughness value for that specific pipe.



Section Size - Display a section size from the list defined in the Section Size Library.



Number of Sections - Number of identical, parallel pipe sections used in the hydraulic calculations.
By clicking the ellipsis (...) button located next to the Material field or the Section Size field, you
can access the respective engineering library to create and customize materials and section sizes.
You can let the program choose a section size for you during an automatic design calculation.

Invert Elevations Section
In this section, you select whether upstream and downstream pipe inverts will be entered by you or set to
the sump elevation of the upstream and downstream node. If Set Invert to Upstream/Downstream
Structure box is not checked, you can set the upstream and downstream invert elevations in this section.
Otherwise, the program will compute the pipe upstream/downstream invert elevations using the
upstream/downstream structure sump elevation and desired sump depth.
User Defined Length Section
If the User Defined Length box is checked, you can enter a pipe length. Otherwise, the program will
compute a pipe length based on the drawn alignment of the pipe. User-defined lengths are useful for
drawing quick schematics to speed along your design process.
User Defined Bend Angle Section
If the User Defined Bend Angle box is checked, you can enter an appropriate bend angle for the purpose
of calculating loss through a junction or inlet structure. If the box remains unchecked, the program will
calculate the bend angle across the junction or inlet structure based on the alignment of the pipe relative to
the downstream pipe.
Hydraulic Summary Section
Here you can view the calculated hydraulic characteristics of a pipe, which include:


Average Velocity - Average velocity of the flow in the pipe, calculated by using one of the available
average velocity methods.



Constructed Slope - The difference in the invert elevations between the upstream and downstream
end of the pipe divided by its length.



Full Capacity - Computed discharge in the pipe when it is flowing full.



Design Capacity (Steady State only) - Computed discharge in the pipe, based on the Design Percent
Full value specified in the Design tab.



Excess Full Capacity (Steady State only) - Difference between the full flow capacity of the pipe and
the actual calculated flow in the pipe.



Excess Design Capacity (Steady State only) - Difference between the design capacity of the pipe and
the actual calculated flow in the pipe.



Total Flow - Total flow in the pipe during the run.

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Pressure Pipe
Pressure Pipe General Tab
The General tab for pressure pipes is organized into the following groups:


Pipe - General pipe data.



Initial Status - Specify whether the pipe is initially open or closed.



Invert Elevations - Displays elevations of the pipe inverts at the upstream (From node) and
downstream (To node) end.



User-Defined Length - Specify whether the pipe length is calculated automatically or user-defined.



Nodes - Displays the nodes at the upstream and downstream ends of the pipe.

• Hydraulic Results - Displays calculated hydraulic data.
For further details, refer to the topics describing each section.
Pipe Section
In this section you enter in all of the pipe general characteristics:


Label - Unique name referencing the pipe in reports, error messages, and tables.



Material - Pipe material, with its associated roughness value, selected from the Material Library.



Diameter - Diameter of the pipe.



Roughness Coefficient - Pipe roughness coefficient or value associated with the roughness method
selected during the project setup (Manning’s n, Hazen-Williams C, or Darcy-Weisbach roughness
height) for the selected material. You can keep the roughness value associated with the selected
material, as defined in the material library, or override the roughness value for that specific pipe.



Minor Loss Coefficient - Coefficient K used in the minor loss equation, as defined in the Minor
Losses section in Appendix B. This is the equation most commonly used for determining the headloss
in a fitting, valve, meter, or other localized component.



Check Valve - When this box is checked, flow can only travel from the From Node to the To Node in
a pressure pipe.
By clicking the ellipsis (...) button located next to the Material you can access the engineering
library to create and customize materials.
By clicking the ellipses (…) button on the Minor Loss Coefficient field, you can access the Minor
Loss elements and generate composite minor loss coefficients to be applied to the pressure pipe.
Set the minor loss coefficient value to 0.0 if there is no minor loss in the pipe.

Minor Loss Elements
Pressure pipes can have an unlimited number of minor loss elements associated with them. This program
provides an easy-to-use table for editing these minor losses. The minor loss table consists of four columns:


Quantity - The number of minor losses of the same type to be added to the composite minor loss for
the pipe.



Minor Loss - The type of minor loss element.



K Each - The headloss coefficient for a single minor loss element of the specified type.

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• K Total - The total minor loss coefficient for the row. It is the Quantity multiplied by the K Each.
The Minor Loss Elements dialog also has three command buttons:


Insert - Insert a row in the table.



Duplicate - Create a new row in the table with the same values as the selected row.

• Delete - Delete the selected row of the table.
The Minor Loss Elements dialog is accessed by clicking the ellipsis (…) button next to the Minor Loss
Coefficient choice list on the Pressure Pipe Editor.
Initial Status Section
The initial status of the pipe can be either Open or Closed. The status can possibly change when
calculations are performed based on the presence of controls for that pipe.
In Steady State Analysis mode, the Initial Status is used as the permanent status. However, it can
be overruled by the presence of controls, if the Use Controls in Steady-State Analysis check box
in the Calculation Options dialog is checked. The Calculation Options dialog is accessed by
clicking the GO button in the main view to display the Calculation tab of the Scenario Editor,
and then clicking the Options button.
Invert Elevations Section
The From Node and To Node Elevations of the pressure pipe can be entered and viewed here. . If Set
Invert to Upstream/Downstream Structure box is not checked, you can set the From and To elevations
in this section. Otherwise, the program will compute the pipe’s From and To elevations using the
upstream/downstream gravity structure’s sump elevation.
Disabled elevations are defined at the connecting node structure. Only inverts that are
connecting to gravity node structures such as wet wells or outlets can be edited. Inverts
connecting to pressure elements such as pressure junctions and pumps cannot be edited.
User-Defined Length Section
If the User-Defined Length box is checked, you can enter a pipe length. Otherwise, the program will
compute a pipe length from node center to node center, accounting for bends if there are any. Creating
user-defined lengths is useful for drawing quick schematics to accelerate your design process.
Nodes Section
Displays the nodes that are upstream (From node) and downstream (To node) of the pipe. If the flow is
traveling from the From Node to the To Node then the flow value will positive. If flow is traveling from
the To Node to the From Node it will be negative. You can reverse the From Node and the To Node by
clicking the Reverse button.
Hydraulic Results Section
This section reports the following hydraulic results:


Pressure Flow - Calculated total flow in the pipe.



Velocity - Calculated velocity in the pipe.



Headloss Gradient - Headloss in the pipe represented as a slope, or gradient.



Pressure Pipe Headloss - Loss of energy in the pipe due to friction and minor losses.

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6.3.2

99

Control Status - Open or closed status of the pipe. Open means that flow occurs in the pipe and
closed means that there is no flow.

Headlosses Tab
The Headloss tab is used to specify the method and parameters that are used to calculate the headlosses
through any structure located at a junction in a gravity network. The Standard, AASHTO, Generic, or
HEC-22 Energy methods are available to automatically calculate headloss based on structure geometry and
flows, or a desired headloss value can be specified directly using the Absolute method. Furthermore, the
model results for the exit pipe, which are often of interest in computing headlosses, can be seen here under
the Exit Pipe Summary. This tab contains three sections:


Headlosses - The headloss method can be selected from the list box from the following choices:


Absolute



Standard



HEC-22 Energy



AASHTO



Generic



Headloss Method Parameters - Parameters dependent upon which headloss method is chosen.



Exit Pipe Summary - Calculated hydraulic properties of the pipe downstream of the junction.

Headlosses Section
The various headloss methods can be selected from the choice list. The methods include the Absolute,
Standard, Generic, AASHTO, and HEC-22 methods. Refer to Appendix B for more information regarding
the theory underlying these methods.

Headlosses Method Section
The items displayed are dependent upon which method is chosen in the Headlosses section. The choices
are as follows:


Absolute - Enter the desired value for headloss at the structure. This method ensures that the headloss
across the structure will be equal to this value regardless of the actual flows or geometry of the
structure.



Standard - Enter the headloss coefficient for the structure. The headloss across the structure will be
equal to this value multiplied by the exit pipe velocity head.



HEC-22 - The HEC-22 Energy method assumes the energy loss across a structure is proportional to
the velocity head of the exit pipe. The proportionality constant takes into consideration several
variables based on structure shape, configuration, plunging flows, and benching of the structure
bottom. An in-depth description of the theory can be found in the Junction Headlosses section
Appendix B of the help, and in Chapter 7 of the HEC-22 Urban Drainage Design Manual. All but one
aspect of the proportionality constant, benching, is determined internally based on known variables
such as structure type, pipe sizes, and angles between pipes. The benching method is user-defined, and
is selected from the list box in the HEC-22 Benching Method field. The following four benching
methods are available:


Depressed - The floor elevation of the structure is lower than the invert elevation of the exit
pipe.



Flat - The floor elevation of the structure is equal to the invert elevation of the exit pipe.

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Half - The floor elevation of the structure is equal to the elevation at the center of the exit
pipe.



Full - The floor elevation of the structure is equal to the elevation at the top of the exit pipe.



AASHTO - The AASHTO headloss method considers several variables when computing the headloss
across a structure. All of these variables can be determined internally except for the shaping of the
structure. You select the shaping method (None or Full) from the choice list. See the Junction
Headlosses section of Appendix B of the help for a discussion of the theory underlying the AASHTO
method.



Generic - The input values used by this method to compute the headloss across a gravity structure are
the upstream and downstream coefficients. The loss across the structure is computed as the
downstream coefficient multiplied by the velocity head in the downstream pipe minus the upstream
coefficient times the velocity head in the governing upstream pipe. Note that if a value of zero is
specified as the value for the upstream coefficient this method will produce the same results as the
Standard Method. Refer to Appendix B for more information regarding this method.

Exit Pipe Summary Section
This area shows the following calculated properties of the exit pipe, which are typically of interest in
determining structure headloss:

6.3.3



Exit Discharge - Discharge in the pipe downstream of the structure.



Exit Velocity - Velocity at the upstream end of the pipe downstream of the structure.



Exit Velocity Head - Velocity head at the upstream end of the pipe downstream of the structure.

Diversion Tab
The Diversion tab is used to define the characteristics of the diversion structure. At this tab you select
whether this element will be a diversion or not. If the Has Diversion box is checked on, flows going out of
this element will be diverted according to the parameters defined on this tab. This tab contains five
sections:


Has Diversion - Check box indicating whether this element should divert flows or not.



Diversion Parameters - Diversion type (overflow or a diversion) and Diversion Target are defined
here.



Diversion Rating Curve Table - Table defining diverted flows as a function of upstream (system)
flows.



Flow Diverted Out - Summary of the flows diverted out of the element at the diversion.



Flow Diverted In - Summary of the flows diverted to this element from other diversions in the system.

Diversion Parameters
The user can specify if and where diverted flow will reenter the model in this section of the Diversion tab.
The user can choose between an overflow diversion target <Overflow> and a diversion target element.
The program will compile a list of available diversion targets that will not create a loop in the system. An
element is available as a diversion target if it is downstream of the diversion element. Any element in
another network can be used as a diversion target, provided that the target network is downstream from the
origin network. A target network is considered to be downstream of the origin network if there is no way
for water to get from the target network to the origin network.
You will not be able to edit the Diversion Target field until the box labeled Has Diversion is checked.

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If diversions create a loop within the system a validation message will pop up at the calculation
time.

Flow Diverted Out
This section of the Diversion tab provides the user with a summary of results for the flows diverted out of
the element.


Percent Diverted Out - Percentage of total flow coming to the diversion element that is diverted out
of this diversion element.



Diverted Flow Out - Total flow that is diverted out of this diversion element.



Non-Diverted Flow Out - Total flow that is not diverted out of this diversion element. This is the
flow that goes to the downstream pipe.



Total Flow Out - The total flow leaving the structure. This includes both the flow that is diverted and
the flow leaving through the downstream pipe.
The sum of the Diverted Flow Out and Non-Diverted Flow Out is equal to the Total Flow Out.

Flow Diverted In
This section of the Diversion tab provides the user with a summary of results for the flows diverted to this
element from other diversions in the system.


Local Diverted Flow In - Sum of the flows diverted to this element from upstream elements in the
same network.



Global Diverted Flow In - Sum of the flows diverted to this element from diversions in other
networks.



Total Diverted Flow In - Total flow that is diverted to this element.
Flow will be diverted to an element if the element is selected as a Diversion Target. Unlimited
number of diversions can divert flow to a single element.

Diversion Rating Curve Table
This section of the Diversion tab is used to specify the diversion rating curve. A diversion rating curve
defines diverted flows as a function of the total system flow. You must specify at least two points in the
Diversion Rating Curve Table. For each point, diverted flow must be smaller than the system flow. The
program uses linear interpolation/extrapolation to determine the values of diverted flows that lie between
the points in the table or outside of the range of the table. If the computed value of the diverted flow is
negative, the program will set the diverted flow to 0.
To be able to edit the Diversion Rating Curve Table you must check the box labeled Has Diversion.

6.3.4

Controls Tab
Pump and Pressure Pipe Controls Tab
Controls allow you to configure the hydraulic model by changing the pump or pipe settings when specific
junction pressures or wet well water levels occur in the network. The following buttons are available:

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Add - This will open the Control dialog, where a new control can be added and the specifics can be
entered.



Edit - Select the description of the control you wish to edit, and click this button. This will open the
Control dialog, where the specifics can be edited.



Duplicate - Duplicates an existing control. Select the description of the control you wish to duplicate,
and click this button.



Delete - Deletes an existing control. Select the description of the control you wish to delete, and click
this button.
Pipes with check valves cannot have controls.

Control Dialog
Several types of information are required to define a control for a pressure pipe or pump. This data is
grouped into the following sections:


Preview - Textual description of the control being edited.



Control - Specify the type of control, either status or setting.



Control Condition - Specify the controlling node and the control setting.

Control Preview Section
The Preview section provides a textual description of the control being edited. The control preview is
continuously updated while you edit a control.
Control Section
This software supports two types of controls:


Status - Controls the Open/Closed status for pipes, or the On/Off status for pumps.



Setting - Controls the relative speed factor of a pump.
Only status controls are available for pipes. Setting controls are not appropriate.
When pumps are turned on by a control, their relative speed factor is set to 1.00.
To activate a closed or inactive valve, use a setting control. Similarly, to turn a pump on at a
relative speed setting other than 1.00, use a setting control.

Control Condition Section
A control can be triggered by a specified pressure or hydraulic grade being reached in any wet well or
pressure junction, or they can also be triggered based on the time during an analysis. This section contains
the following fields:
• Condition - You can specify a time based or node based condition.
When Node is the selected condition, the control will be triggered based on the hydraulic grade or pressure
at the selected pressure junction or wet well, and you must specify the following information.


Node - Specifies the controlling node.

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103

Comparison - Triggers the control when the specified junction or wet well's hydraulic parameter is
above or below the node condition's hydraulic parameter.



Hydraulic Grade or Pressure - The control conditions at the control node can be expressed in terms
of hydraulic grade or pressure. Depending on which is chosen, the software will display the calculated
value of the other.
Example: Closed when node J-2 below 10 psi - means that when the pressure at junction J-2 is below 10
psi, the controlled pipe will close.
When Time is the selected condition, the control will be triggered when the selected time is reached during
an EPS. You must specify the following information:
• Time - When this time is reached during an EPS the control will be triggered.
Example: Close at time 4.00 hr - means that when the simulation reaches hour 4 the controlled pipe will
close.

6.3.5

Profile Tab
This tab contains information about the physical properties and calculated profile of the flow through the
pipe. This tab is divided into three sections:


Upstream Elevations - Displays elevations related to the upstream end of the pipe.



Downstream Elevations - Displays elevations related to the downstream end of the pipe.



Profile - Displays the type of profile exhibited by the flow through the pipe, and the energy slope and
headloss in the pipe.

Pipe Elevations Section
Elevation information is grouped into two sections on the Profile tab, upstream on the left and downstream
on the right, related to the two pipe ends. The upstream and downstream elevation information includes:


Ground elevation - Elevation of the ground surface at the node, edited in the Element Editor for that
node.



Cover - Distance between the crown (soffit) of the pipe and the ground surface elevation.



Crown - Elevation of the top of the pipe section.



Hydraulic Grade - Hydraulic grade at the ends of the pipe.



Depth - Flow depth at the ends of the pipe.



Invert - Elevation of the pipe invert.

Pipe Profile Section
This section contains the following information:


Description - Displays the profile type that the flow exhibits as it travels through the pipe. In the case
of a composite profile, this section will display all the profile types.



Energy Slope - The result of dividing the headloss per pipe length.



Headloss - The total headloss through the pipe.



d/D (depth/Rise) - A ratio of the average depth ((Depth Upstream + Depth Downstream) / 2) in the
pipe to the pipe’s rise.

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Design Tab
Manholes, Junction Chambers, and Outlets
Design Tab (for Manholes, Junction Chambers, and Outlets)
The Design tab provides an interface for entering the nodal constraints for SewerCAD’s automated design
feature. Manholes, junction chambers, and outlets all support the following groups of constraints:


Local Pipe Matching Constraints - If you toggle this on, you can enter pipe matching constraints
specific to this junction structure.



Design Structure Elevation - Specifies if the program is to design the structure’s sump elevation
during an automatic design.

Local Pipe Matching Constraints Section
Check the box in this section if you want to specify pipe matching constraints for the structure that are
different from the Design Alternative’s default values. During an automatic design, the program will adjust
the elevations of the pipes adjacent to the structure according to the structure’s matching constraints. The
two choices for matching are Inverts and Crowns. Additionally, the downstream pipe can be offset from
the upstream pipe(s) by a specified amount. This value is called the Matchline Offset. The program also
supports the design of drop structures. In some situations, drop structures can minimize pipe cover depths
while maintaining adequate hydraulic performance. This can be done by clicking the Allow Drop
Structure check box.
Design Structure Elevation Section
Check the box in this section if you want the structure’s sump elevation adjusted during an automatic
design. If this box is checked, the Desired Sump Depth field becomes editable. The sump depth is the
distance below the lowest pipe invert.

Gravity Pipe
Pipe Design Tab
The Design tab for pipes allows you to customize the automatic design process for a particular pipe. You
can specify whether the pipe will be designed, and, if so, how the automated design process should be
constrained. This tab is divided into the following sections:


Design Pipe - If this box is checked, the program will automate the design of the pipe.



Part Full Design - Allows you to tell the program to design the pipes in the system so the depth of
flow is a percentage of the pipe diameter.



Allow Multiple Sections - Allows the automatic design process to use several identical pipes in
parallel.



Limit Section Size - Allows you to limit the section sizes from the Section Size Library to be used
during automatic design process.



Range Constraints - Displays the desired cover, slope, and velocity conditions for the pipe design
process.

Design Pipe Section
If the Design Pipe box is checked, the program will automate the design of the pipe. You can also select
whether the program should adjust the upstream and downstream invert during the design process by
checking the Design Upstream Invert and Design Downstream Invert boxes, respectively. If these
boxes are not checked, the inverts will reflect the user-defined values entered under the Pipe General tab.
Finally, you can choose to specify local design constraints by checking the box labeled Specify Local

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Constraints. This will enable the fields in the Range Constraints Section and allow you to set constraints
specific to the pipe. These local constraints override the default design constraints set through the Analysis
menu.
Part Full Design Section
If the Specify Local Constraints box in the Design Pipe section is checked, you can specify the Design
Percent Full target to be used by the design algorithm. Thus, pipes may be sized such that the depth of
flow is a percentage of the pipe diameter.
Allow Multiple Sections Section
If the Specify Local Contraints box in the Design Pipe section is checked, you can choose to let the
design algorithm adjust the number of sections in parallel, up to the specified Maximum Number
Sections.
Limit Section Size Section
If the Specify Local Contraints box in the Design Pipe section is checked, you can limit the pipe section
height to a Maximum Section Rise value during the design process.
Range Constraints Section
If the Specify Local Constraints box in the Design Pipe section is checked, you have the option to set the
boundary conditions for the pipe design process. You can set the following design constraints: Minimum
and Maximum Velocity, Minimum and Maximum Cover, and Minimum and Maximum Slope.

6.3.7

Section Tab
Section Tab (for Wet Wells)
The wet well section data includes the information necessary to describe the storage characteristics of a wet
well. These characteristics have been factored into the following groups:


Section - The type of cross section and the basic storage parameters.



Cross Section - Parameters describing the cross sectional geometry.



Operating Range - The minimum, initial, and maximum operating elevations.

Wet Well Section Section
The general information under the Section heading for wet wells is:


Section - Choose the type of cross section for the wet well. There are two types of cross sections to
choose from - Constant Area and Variable Area.



Inactive Volume - Enter the inactive volume for this wet well, as defined in the illustration on this
dialog.



Total Active Volume - If this is a Constant Area wet well, the total active volume will be computed
from the other wet well data and this field will not be editable. If this is a Variable Area wet well,
enter the total storage volume for the wet well.
Wet well section characteristics do not affect the results or simulation during a Steady-State
Analysis. The volume and storage capacity of the wet well are utilized during an Extended
Period Simulation.

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Cross-Section Section
The two basic types of wet wells are Constant Area and Variable Area. The Cross Section section changes
depending on which type is chosen. The alternatives are as follows:




Constant Area - The cross sectional geometry of the wet well is constant between the minimum and
the maximum operating elevations. Two parameters are needed to fully describe a constant area wet
well section:


Cross Section - Choose whether the cross section is circular or non-circular.



Average Area/Diameter - Enter the average area of the non-circular cross section, or the
diameter of the circular cross section.

Variable Area - The cross sectional geometry of the wet well varies between the minimum and
maximum operating elevations. The following input is available to describe the variable area:


Depth Ratio/Volume Ratio Table - Enter a series of points describing the storage
characteristics of the wet well. For example, at 0.1 the total depth (depth ratio = 0.1) the wet
well stores 0.028 the total active volume (volume ratio = 0.028).

The storage characteristics of the wet well can be plotted. Choose Tank Curve from the Report
Button at the bottom of the Wet Well dialog.
Wet well section characteristics do not affect the results or simulation during a Steady-State
Analysis. The volume and storage capacity of the wet well are utilized during an Extended
Period Simulation.

Operating Range Section
This is where you can set the absolute limits for the water levels in a wet well. The range can be defined in
terms of Elevations or Levels. Elevations are relative to the same datum as the rest of your system, while
levels refer to heights of water above the wet well's base elevation. The associated fields prompt you for
the following values:


Maximum - This is the highest water surface elevation or level in the wet well.



Alarm - If the HGL in the wet well goes above the alarm elevation or level during the analysis then a
warning message will be generated during that time step.



Initial - The use of this parameter depends on whether the Fixed Level toggle is set to On or Off
during a Steady-State Analysis. Refer to the Hydraulic Transition from Gravity to Pressure topic in
Appendix B for a further explanation. During an Extended Period Simulation this value represents the
starting elevation at the beginning of the simulation.



Minimum - Lowest water surface elevation or level in the wet well.



Base - The elevation of the base of the wet well.



Fixed Level - When this checkbox is checked, the level in the tank will not be adjusted to reflect the
tank inflow during a Steady State analysis, and the initial level described above will be used as the
HGL. The Fixed Level checkbox has no effect when running an EPS analysis.
The initial elevation must be between the maximum and minimum elevations.

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107

Loading Tab
SewerCAD classifies loads as sanitary (dry weather) loads, wet weather loads, and known flows.
Sanitary loads correspond to loads produced by residential, commercial, recreational, and industrial
activity. A sanitary load represents the base load to the sewer system. Wet weather loads are related to
rainfall activity. They are caused by groundwater infiltration and rainfall inflow.
The Loading tab for manholes, wet wells, and pressure chambers is organized into the following groups:


Sanitary (Dry-Weather) Flow - Table containing a collection of sanitary loads.



Inflow - Table containing a collection of wet weather loads, and is accessible only for wet wells and
manholes.



Known Flow - Used to model a local load entering a manhole or wet well if, for instance, you have
computed the hydrology using an external method such as the TR-55 tabular method. The Known
Flow field is accessible only for wet wells and manholes.

Sanitary (Dry-Weather) Flow Section
The Sanitary Flow section is specified as a collection of sanitary loads applied to the selected node. The
following types of loads can be applied:


Hydrograph - Flow vs. Time - A flow vs. time distribution



Unit Load - Unit Type & Count - The type of Unit Load and the number of units associated with
Unit Load. For example, 5000 passengers at an Airport.

• Pattern Load - Base Flow & Pattern - A direct, known sanitary load with a set pattern.
The following operations can be performed on the Sanitary Flow list in the section:


Add - Add a new load to the Sanitary Flow list.



Edit - Opens the editor for an existing load in the list.



Delete - Deletes a sanitary load from the list.



Pie Chart - Generates a pie chart that depicts the distribution of the sanitary loads in the list.

Inflow Section
The Inflow section is specified as a collection of wet weather loads applied to the selected node. The
following types of loads can be applied.


Hydrograph - Flow vs. Time - A flow vs. time distribution

• Pattern Load - Base Flow & Pattern - A base wet-weather load with a set pattern.
The following operations can be performed on the Inflow list in the section:


Add - Add a new load to the Inflow list.



Edit - Opens the editor for an existing load in the list.



Delete - Deletes an inflow load from the list.
The Inflow section is only available for wet wells, pressure junctions, and manholes.

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Infiltration Tab
This tab allows you to enter and view the infiltration data (direct and additional) for a gravity pipe. The
following sections are available:


Infiltration - Infiltration can be estimated proportionally to gravity pipe characteristics such as length
or number of pipe defects. Depending on the Infiltration Type specified, an additional section
appears containing fields for entering the infiltration loading unit and rate, pattern load, or hydrograph
information.



Local - Contains a field for displaying the local infiltration as specified in the previous sections, as
well as an Additional Infiltration field for entering a lump sum infiltration.



System - Displays the cumulative infiltration resulting from the upstream pipe network.

Infiltration Section
Four types of direct infiltration are supported, as specified in the Infiltration Type choice list:


Pipe Length



Pipe Diameter-Length



Pipe Surface Area



Count Based (this may be used to account for infiltration proportional to the number of pipe defects)
Direct infiltration is defined by:


Infiltration loading unit - Unit that is used to define infiltration rate.



Infiltration rate per loading unit - Rate of infiltration for each infiltration loading unit.

In addition to the four direct infiltration types, the following time-based loading types can be selected from
the Infiltration Type list as well:


Hydrograph



Pattern Load

Infiltration Hydrograph
SewerCAD also allows infiltration to be defined as a direct hydrograph into the gravity pipe. When
Hydrograph is chosen from the Infiltration Type pull-down menu, a table will appear where time/flow
data can be added.
The following operations can be performed on the table:


Insert - Inserts a row in the table above the selected row



Duplicate - Duplicates the selected row



Delete - Removes the selected row from the table

Infiltration Pattern Load
A Pattern Load is defined by a single base load and a pattern, which is a series of multipliers that define
how the base load is distributed over time.
If the Pattern is set to fixed then the infiltration load is constant over time. You can enter the Pattern
Manager by clicking the ellipses (…) button in the Pattern field.
When running a Steady-State analysis the infiltration load is equivalent to the base load regardless of the
pattern.

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Local Section
This section consists of the following fields:


Local Infiltration - The infiltration entering the pipe as defined in the Infiltration section.



Additional Infiltration - Used to specify a lump sum infiltration amount.



Total Infiltration - The sum of the additional infiltration and direct infiltration.

System Section
This section consists of the following fields:

6.3.10



System Infiltration - The cumulative infiltration resulting from the upstream pipe network.



System Additional Infiltration - The cumulative additional infiltration resulting from the upstream
pipe network.



System Total Infiltration - The cumulative total infiltration resulting from the upstream pipe network.

Cost Tab
On this tab, you can specify whether or not the element is to be included in the cost analysis. If the element
is selected to appear in the cost analysis then you can enter the costs associated with the element. This tab is
comprised of the following components:


Include in Cost Calculation? - A check box that allows you to control whether or not this element
will be included in the cost analysis. If this box is checked, the element will be included in the cost
calculation.



Construction Costs - Contains a table for an element for entering cost items that can be expressed in
terms of a quantity, unit, and unit cost.



Non-Constructions Costs - Contains a table for entering costs related to the elements that need to be
expressed as either a lump sum or as a percentage of the construction costs.

Include In Cost Calculation?
This check box allows you to control whether or not this element will be included in the cost calculation. If
this box is checked, the element will be included in the cost calculation. If you are modeling a new
subdivision, most of the elements in your model will probably be included in the cost calculation. However,
if you are adding onto an existing system, you may only calculate the cost for a small portion of the total
elements in your system.
The value of this field can be varied by alternative. This can be useful if you want to compute the costs for
different portions of your system separately. For instance, if you have several phases of construction that
you want to cost separately, you could create one cost alterative that only includes elements in phase one,
and another alternative that only includes elements in phase two. When you perform your cost analysis, you
can then get cost reports detailing each phase of construction.

Non-Construction Costs
The Non-Construction Costs section of the Cost tab contains a table that allows you to enter an unlimited
number of non-construction cost items for each element. A non-construction cost item can be specified as
either a lump sum value or as a percentage of the total construction costs for the element. Each nonconstruction cost contains the following four components.


Label - A unique name that identifies the non-construction cost item. The labels must be
different for all non-construction cost items in a table.

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Factor - A numeric value that is used in conjunction with the operation to compute the cost
for a non-construction cost item.



Operation - The operation that will be applied against the factor to compute the total cost for
the non-construction cost item. The two possible values for this field are lump sum or
percentage of the total construction costs.



Cost - The cost of the non-construction cost item.

Construction Costs
The Construction Costs section of the Cost tab consists of the following two components:


Construction Costs Table - This table allows you to specify an unlimited number of
construction costs for each element.



Advanced Construction Costs Options - This button is only available for elements such as
pipes, inlets, gravity junctions, and manholes that support Unit Cost Functions. Clicking this
button accesses advanced options for the selected construction cost item.

Construction Costs Table
The construction costs table allows you to specify an unlimited number of construction cost items for each
element. Each construction cost item is composed of four basic characteristics which are listed below.


Label - This is a string that identifies the construction cost item. It must be unique for every
construction cost in the table.



Quantity - This field holds a numeric value that will be multiplied by the unit cost to compute
the total cost for the construction cost item.



Unit - The value in this field signifies the unit of the value held in the quantity field. For
pipes, this field can be either a length unit or "each." For nodal elements this field is a userdefined string.



Unit Cost - The is the cost per unit specified in the unit column. For instance, for a pipe it
could be cost per length. This value is multiplied by the quantity to calculate the total cost for
the construction cost item. If a Unit Cost Function is assigned to a construction cost item
then this field will not be editable as the value will be computed based on the Unit Cost
Function.



Total Cost - This is calculated by multiplying the unit cost by the quantity. The value in this
field is always calculated by the program.

Advanced Construction Cost Options
Construction cost items for pipes and gravity structures (inlets, manholes, and junction chambers) have a
set of advanced options. Under these advanced options, you can specify a Unit Cost Function to associate
with a construction cost item. A Unit Cost Function describes the relationship between the unit cost for a
construction cost item and the value of an attribute of the element. For instance, the unit cost for a pipe
may be a function of the diameter. If you assign a Unit Cost Function to a construction cost item then the
unit cost for that item is automatically updated as the physical characteristics of the element change.
For pipes there is an additional advanced option Set Quantity Equal to Pipe Length, which allows you to
set the quantity field for a construction cost item equal to the length of the pipe.

6.3.11

User Data Tab
The User Data tab allows you to view and edit the customizable user data for each element. This tab is
composed of two sections:

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User Data - Any Date/Time, Number, Text, and Yes/No data defined by the user.

• User Memos - Any memo data fields defined by the user.
For information on how to add new fields or edit an existing field format, see the Help on the User Data
Extension dialog.
Default user-defined attributes are provided. These can easily be deleted or modified.
User Data Extensions are a powerful way to add your own data to the project. This data will not
affect the hydraulic calculations in any way, but can be used as any other data for operations
such as sorting, annotating, reporting, and importing/exporting.

User Data Section
This section contains a list of Date/Time, Number, Text, and Yes/No user data fields, displayed as single
line fields. User data fields are defined in the User Data Extension dialog.

User Memos Section
This section contains a list of any memo fields displayed as multiple line scrolling text panes. User memos
are defined in the User Data Extension dialog.

6.3.12

Message Tab
All Element Editors have a Messages tab, which contains three parts:


Message List - Contains information that is generated during the calculation of the model, such as
warnings, errors, and status updates.



Description - An informative statement that you may enter about the element.



Notes - Contains notes that you enter, and may include a description of the element, a summary of
your data sources, or any other information of interest.
Messages, descriptions, and notes will be printed in any element report.

6.4 Loading Dialogs
6.4.1

Add New Load Dialog
Whenever an Add button is clicked under the Loading tab or when adding loads from within the Sanitary
(Dry Weather) Loading and Infiltration and Inflow Loading alternatives, the Add New Load dialog
will open up allowing you to select an appropriate load type to add as a load to the current element.
Select from the following load definitions:


Hydrograph - Flow vs. Time



Unit Load - Unit Type & Count (sanitary (dry-weather) loads only)

• Pattern Load - Base Flow & Pattern
When the OK button is clicked, a dialog will open where data associated with the selected load definition
can be entered.

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Base Load Dialog


Unit Sanitary (Dry Weather) Load - Unit sanitary loads define the type of the load (for instance
Apartment or Airport). Unit sanitary loads are selected, edited, and created in a Unit Sanitary (Dry
Weather) Load Library, which is accessed by clicking the ellipsis (…) button next to this field.



Sanitary Unit Load Units - Represents the local count of loading units for the selected unit sanitary
load.



Loading Unit - Individual entity inside the unit sanitary load (for instance Resident or Passenger)
generating sewage.



Unit Load - Sewage flow generated by one loading unit.



Base Load - Average local sanitary load resulting from the category chosen under the Unit Sanitary
(Dry Weather) Load column. This value is computed by multiplying the loading unit count by the
unit load for each unit sanitary load and summing them up.
Base load represents the average sanitary loads to the system. During a Steady-State analysis
actual design sanitary loads are calculated using Extreme Flow Factor methods such as variable
peaking methods, which account for various effects like system routing. During an Extended
Period Simulation patterns can be applied to specific unit sanitary loads to describe how the load
varies over time.

6.4.3

Hydrograph Dialog
Hydrograph information is entered through this dialog.


Label - A unique label that serves as an identifier for the set of hydrograph data.



Hydrograph - In this table, the time / discharge data can be entered. The following functions can be
performed on a row in this table:


Insert - will insert a new row above the selected row in the table.



Duplicate - will create a copy of the selected row.



Delete - will remove the selected row from the table.

By clicking the Notes tab you can enter in relevant information about the hydrograph. You can
also create a graph of the hydrograph by clicking the Plot button.

6.4.4

Pattern Load Dialog
A Pattern Load consists of a single base load and a loading pattern that describes how that load varies over
time for an Extended Period run.
If the pattern selected in the Pattern field is Fixed then the entered base load will remain constant over the
entire Extended Period Simulation.
During a Steady State analysis the base load is used as the load regardless of the pattern entered.

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6.5 Prototypes
Prototypes allow you to enter default values for the elements in your network. These default values are
used while laying out the network. Prototypes can reduce data entry requirements dramatically if a group
of network elements share common data. For example, if a section of the network contains all concrete
pipes, use the pipe prototype to set the Material field to concrete. When a new pipe is created, its material
attribute will default to concrete.

Changes to the prototypes are not retroactive and will not affect any elements created prior to
the change.
You can use the FlexTable Global Editing feature to change the data for any group of elements.
If a section of your system has distinctly different characteristics than the rest of the system,
adjust your prototypes before laying out that section. This will save time when you edit the
properties later.
You can configure the element prototypes at the beginning of a new project during the Project Setup
Wizard. You can also select Tools / Prototypes from the pull-down menu to edit the prototypes for the
project at any time.

6.6 User Data Extensions
User Data Extensions are a set of one or more fields that you can define to hold data to be stored in the
model. The User Data Extension feature allows you to add your own data fields to the project. For
instance, you can add a field for keeping track of the date of installation for an element, or the type of area
serviced by a particular element.
User Data Extensions exhibit the same characteristics as the pre-defined data used in and produced by the
model calculations. This means that User Data Extensions can be imported or exported through database
and Shapefile connections, viewed and edited in FlexTables, included in tabular reports or element detailed
reports, annotated in the drawing, color coded, and reported in the detailed element reports. This data can
also be accessed on the User Data tab of each Element Editor dialog.
The user data does not affect the hydraulic model calculations. However, their behavior
concerning capabilities like editing, annotating, sorting and database connections is identical to
any of the standard pre-defined attributes.

6.6.1

User Data Extensions Dialog
The User Data Extension dialog holds a summary of the user data extensions currently defined in the
project. In this dialog, there is a tab for each type of element. By clicking a particular tab, you can access
the user data extensions currently defined for that type of element. The software initially contains default
user data extensions, but these can be deleted or edited. Each tab in the User Data Extension dialog is
composed of a table listing characteristics of the user data extensions defined for that type of element. In
addition, there are a series of buttons that can be used to add, edit, delete, and share individual user data
extensions. The table listing the user data extensions consists of the following four columns:


Label - Description that will appear next to the field for the user data extension, or as the column
heading if the data extension is selected to appear in a FlexTable.

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Type - Lists the type of data that is valid for the data extension. The available data types are
Date/Time, Number, Text, Memo, and Yes/No.



Unit / Picture - Contains the unit of each numeric data extension, or the date and time presentation
format for Date/Time data extensions. Both the unit and the date and time representations are
specified when you create the data extension. They can always be modified by editing the data
extension.



Shared - If an asterisk appears in this column, it indicates that the user data extension is shared among
two or more types of elements. See explanations on the Existing Fields to Share With dialog for
more details.
The following list describes the four buttons that appear on the right side of the table:


Add - Adds a new User Data Field. The User Field Specification dialog will open when you click
this button. Here, you can define the properties of the user data extension that you are adding.



Edit - You can edit an existing user data extension by highlighting the data extension you wish to edit
and clicking this button. This will open the User Field Specification dialog where you can change the
properties for that item.



Delete - You can delete a data extension by highlighting it and clicking this button. If the data
extension you are deleting is shared among multiple types of elements, it will only be removed from
the element type that you are currently editing. If you remove a user data extension, all the
information contained in that field will be permanently removed.



Share - You can open the Existing Fields to Share With dialog by clicking this button. Here, you
pick which of the available attributes defined for other types of elements you would like to share with
the current type of element.
At the bottom of the User Data Extension dialog is a File button that allows you to import or save a set of
user-defined data extensions. You can save the current configuration of user data extensions for later use
by selecting File / Save, and specifying a file location and name. The file extension for the files holding
the user data extension configurations is '.udx'. Select File / Import to merge the data extension
configurations defined in these files into the current project. Importing a '.udx' file will not remove any of
the other data extensions defined in your project. User data extensions that have the same name as those
already defined in your project will not be imported.
To access the User Data Extensions dialog, click Tools / User Data Extensions… from the pull-down
menus.

User Field Specification Dialog
The properties defining a user data extension can be viewed and edited in the User Field Specification
dialog, which is composed of two tabs:
Type - Enter the user data specification.
Notes - Enter any notes related to the User Data Specification.
Type Tab
The Type tab is composed of two sections:
Type - Contains fields for entering the label for the user data extension, as well as the data type.
Format - Contains fields for defining the specification of the type of user data extension selected in the
Type section.

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Type Section
The Type section contains fields for entering the label and data type for the user data extension. The name
entered in the Label field corresponds with the User Data Extension field on the User Data tab of the
Element Editor. This label will also be used as the column heading if the user data extension is added to a
FlexTable.
If you want the label to be displayed on multiple rows when it is used as a column heading, you can use
forward slashes to specify the location of line breaks. When the label is used as a field label in a dialog, the
forward slashes will be converted to spaces. In FlexTables, there is an option to use abbreviated labels for
the column headings. If you want an alternative label to be displayed, you can specify an abbreviated label
after the original label, and separate them by the bar symbol, '|'. When the option to display abbreviated
labels is enabled in the FlexTables, this is the text that will be used as the column heading. For instance, if
you specified the label 'Date/Installed | Date/Inst.' it will be displayed in one of the following three ways,
depending on the location and options selected.

Field Label
(Reports/Element
Dialogs)

Column
Heading
(FlexTable)

Column heading with
abbreviated label option
selected
(FlexTable)

Date Installed

Date
Installed

Date
Inst.

You can select from five different types of data for the user data extension from the drop-down list in the
Type field. An explanation of each is presented in the list below:


Date/Time - Use this data type when you want the values you are entering to be in a standard date and
time format. This format can be more useful than storing date information in a simple text field
because it allows the dates to be sorted correctly when they appear in a FlexTable.



Memo - If a user data extension is defined to be a memo, it will appear as a scrolling text pane in the
User Memos section of the User Data tab in the Element Editor dialog.



Number - Use this data type for fields that contain numeric values. You can specify a unit for the
information in this field. The values contained in this field will then be automatically converted if you
change the unit for this field.



Text - Use this data type to create a single-line text field.



Yes/No - Use this data type to display the attribute as a check box to represent true/false data.

Format Section
This section is enabled only if you select Date/Time or Number in the Type section. Here is where you
define the properties governing the type of data selected.
Number Format - If the type of data you selected was numeric, you can select a unit type (length, volume,
intensity, etc.), a unit, a display precision, and whether to use scientific notation. There are no format
options for memo, text, and Yes/No data types.
Date/Time Type Format - If you selected the Date/Time type, you can specify whether you would like
the date or time to appear first in the input field, as well as the format of the date and time information. The
format in which the date and time information will be displayed can either be selected from the drop-down
lists, or you can type your own custom format directly into the Date Picture and Time Picture fields. If
one of these fields is left blank, the corresponding information will not be displayed.

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The Date/Time data type consists of an input and an output format. The input format is a fixed format that
is determined by the regional settings on your computer. Whenever you enter information into a
Date/Time field, the information must be entered according to the input format. If it is not entered in the
proper input format, the value will simply revert to the original value.
The output format is simply a mask that defines the manner in which the date and time information will be
displayed. It does not affect the way the date and time information can be entered into a Date/Time field.
The output format can be edited as follows:


To specify dates with no leading zeros for single-digit days, years, or months, use lowercase d,
lowercase y, or uppercase M.



To specify dates with leading zeros for single-digit days, years, or months, use lowercase dd,
lowercase yy, or uppercase MM.



To specify abbreviations for the day, year, or month, use lowercase ddd, lowercase yyy, or uppercase
MMM.



To specify the full name of the day, year, or month, use lowercase dddd, lowercase yyyy, or uppercase
MMMM.
If there are characters in the output format that do not map to valid date or time information, then the actual
value of the character will be displayed. For example, if you wanted the date to be displayed as June 15,
1998, you would define the format as 'MMMM d, yyyy'. Since the spaces and comma do not map to any of
the date information, their actual values are displayed. To include a piece of text that contains a character
that maps to the date or time information, use single quotation marks (') around the text.
Notes Tab
This tab contains a text pane for entering notes about the current data extension. The text entered here is
not displayed anywhere in the model, but allows you to keep records for a particular data extension.

Existing Fields to Share With Dialog
This dialog allows you to choose which of the available attributes defined for other types of elements you
want to share with the current type of element. The following sections are available:




Available Items - Lists attributes defined for other element types that have not already been shared
with the current type of element. In order to add attributes to the current element type, highlight them
and click the Add button to transfer them to the Selected Items list.

Selected Items - The attributes in the Selected Items list will be added to the current element after you
click the OK button.
All the characteristics (such as data type, format, unit, and display precision) for a particular user data
extension are the same for all the elements that share it. This is useful when the attribute you are adding
needs to be the same for all the element types for which it is defined. For instance, if you have a Date
Installed field for every element, sharing guarantees that the date format is the same for every element and
will appear in a single FlexTable column. If, at a later point, you decide the date should be in a different
format, you can change the format for one type of element. That change will filter through to all the
elements that share that attribute.

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7.1 Tabular Reporting Overview
FlexTables provide you with a powerful data management tool that can be used to edit input data and
present output data in a quick, efficient manner. Haestad Methods provides you with default element
tables. However, these tables can be customized to fit your particular needs. You can also create your own
tables combining various input and output data for different model elements. You can use FlexTables to
view all elements in the network, all elements of a specific type (e.g. all pipes), or any subset of elements.
Additionally, tables can be filtered, globally edited, and sorted to ease data input and present output data for
specific elements.
FlexTables may also be used for creating results reports that can be sent to a printer, a file, the Windows
clipboard, or copied to your favorite word processing and spreadsheet software.

7.2 Table Manager
The Table Manager provides support for creating, opening, and managing tables. Although the predefined
tables provide access to most of the network element information, it is sometimes practical to present
model results and input data through user-defined tables. The Table Management button provides the
following tools for manipulating user-defined tables:


OK - Open the selected table.



Close - Exit the Table Manager dialog without opening a table.



Table Management / New - Create a new table using the Create New Table and Table Setup dialogs.



Table Management / Edit - Modify the layout of the selected table using the Table Setup dialog.



Table Management / Rename - Rename the selected table.



Table Management / Duplicate - Duplicate the selected table for additional customizing. This is a
very useful feature when you need to change a predefined table.



Table Management / Delete - Delete the selected table.



Table Management / Reset - Reset a table’s units to the current unit system or reset a predefined table
to factory defaults.
You cannot rename or delete the predefined tables that come with this software.
When you choose to print a table, the table name will be used as the title for the printed report.
You can change the report title by renaming the table.

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To access the Table Manager, select the Tabular Reports button
Report / Tables from the pull-down menu.

7.2.1

on the main toolbar, or choose

Creating New Tables
To create a new table, open the Table Manager by clicking the Tabular Reports button
on the
main toolbar, or by choosing Report / Tables from the pull-down menu. In the Table Manager dialog,
click the Table Management button and select New.

7.2.2

1.

Specify the Table Type to indicate the type of network elements you want to display in your
table.

2.

Specify either a one or two row display for your table (in SewerCAD or StormCAD).

3.

Enter the name of your new table in the Enter the description for this table: field. This name
will also be used as the report title when this table is printed.

4.

Click OK to accept these settings and proceed to the Table Setup dialog where you can define
your table.

Two Row Tables
Two-row tables allow you to present more information in fewer columns by pairing up attributes, such as
Upstream and Downstream Node for pipes, or Ground and Sump Elevation for nodes. The DOT Report is
an example of a two-row table. You can only specify the number of rows when you create the table. You
cannot change the number of rows in an existing table.
If you choose to use a two-row table, only the attributes that can be represented in pairs will
actually make use of two rows. Attributes that cannot be represented in pairs will only make use
of the first row. The cell in the second row will be empty.
Global Edit is not available in two-row tables.

7.2.3

Editing Tables
The Edit option allows you to modify the list of attributes that will appear in your table.

7.2.4

Duplicating Tables
The Duplicate option allows you to create a new table based on an existing table.

7.2.5

Deleting Tables
The Delete option allows you to delete any table that you have defined. You cannot delete the predefined
tables.

7.2.6

Renaming Tables
The Rename option allows you to change the name of any table that you have defined. You cannot rename
any of the predefined tables.
The table name will be used as the title in printed reports. You cannot rename any of the
predefined tables. If you need to rename a predefined table, duplicate it first and then rename it.

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7.2.7

119

Resetting Tables
Reset Units to the Current Unit System - This option is only available for tables that are in Local Units
mode. Local Units mode allows the table to maintain its own "local" set of column properties, such as units
and precision. Use this option to reset all units in the selected table to the defaults for the current unit
system, which refers to the units used in the current project. You will be prompted to confirm before this
action is performed.
Reset to Factory Defaults - You can reset any of the predefined tables to the factory defaults. This option
is not available for tables that you create.
To reset units to the current unit system select Table Management / Reset / Reset Units to <the current
Unit System> in the Table Manager.
To reset the table to factory defaults select Table Management / Reset / Reset to Factory Defaults… in
the Table Manager.

7.3 Table Setup Dialog
The Table Setup dialog allows you to customize any table through the following options:


Table Type - Allows you to specify the type of network elements that will appear in the table. For
example, only pipes will appear in a "pipe" table.



Available Columns - Contains all the attributes that are available for your table design, and will
change based on the Table Type field.



Pick Button - You can click on this button to access the categorized Quick Attribute Selector for
selecting columns to be added to the tabular report. The selected column will be highlighted in the
Available Columns Window to be easily added to the Selected Columns as seen fit.



Selected Columns - Contains attributes that will appear in your custom designed table. When you
open the table, the selected attributes will appear as columns in the table in the same order that they
appear in the list. You can drag and drop or use the up and down buttons to change the order of the
attributes in the table.



Allow Duplicate Columns - An advanced feature that allows you to place two identical columns in the
same table and set them to different unit systems.



Column manipulation buttons - Allows you to select or deselect columns to be used in the table, as
well as to arrange the order in which the columns will appear.
The number next to the Selected Columns label indicates the number of columns that will appear
in your table.

To access Table Setup from the Table Manager, highlight the desired table and select Edit from the
Table Management menu button.

7.3.1

Table Type
The Table Type field allows you to specify the types of elements that will appear in the table. It also
provides a filter for the attributes that appear in the Available Columns list. When you choose a table
type, the available list will only contain attributes that can be used for that table type. For example, only
pipe attributes will be available for a "pipe" table.

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Available Table Columns
The Available Columns list is located on the left side of the Table Setup dialog. This list contains all of
the attributes that are available for the type of table you are creating. The attributes displayed in yellow
represent non-editable attributes, while those displayed in white represent editable attributes.

7.3.3

Selected Table Columns
The Selected Columns list is located on the right-hand side of the Table Setup dialog. The attributes in
this list will appear as columns in the table when it is opened. The columns will appear in the same order
as the attributes in the selected list.
To add columns to the Selected Columns list:

7.3.4

1.

Select one or more attributes in the Available Columns list.

2.

Click the Add button [>] or drag and drop the highlighted attributes to the Selected Columns list.

Table Manipulation Buttons
The Add and Remove buttons are located in the center of the Table Setup dialog.
[ > ]

Adds the selected item(s) from the Available Columns list to the Selected Columns list.

[ >> ]

Adds all of the items in the Available Columns list to the Selected Columns list.

[ < ]

Removes the selected item(s) from the Selected Columns list.

[ << ]

Removes all items from the Selected Columns list.

To rearrange the order of the attributes in the Selected Columns list:
1.

Highlight the item to be moved.

2.

Move it up or down in the list by clicking the up or down button located below the Selected
Columns list, or by simply dragging it to the desired location.

You can select multiple attributes in the Available Columns list by holding down the Shift key or
the Control key while clicking with the mouse. Holding down the Shift key will provide group
selection behavior. Holding down the Control key will provide single element selection behavior.
The items displayed in yellow represent non-editable columns (e.g. columns that contain
calculated data) while those in white represent editable columns (e.g. columns that contain input
data).

7.3.5

Allow Duplicate Columns
Set this check box to allow duplicate columns in a table. Allow Duplicate Columns is an advanced feature
that allows you to place two identical columns in the same table and set them to different unit systems.

7.4 Table Window
The Table window is where you will perform most of your data input and review. It has many features to
assist you with data entry, data formatting, report customization, and output generation. To access the
Table window, highlight a table in the Table Manager, and click OK. Here are some of the topics that
will be covered in this section:

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121

Table Navigation

• Table Customization
Options:


Sorting Tables



Filtering Tables



Changing Column Headings



Globally Editing Data



Local vs. Synchronized Units



Mixing Units in a Tabular Report



Abbreviated Labels

• Changing Column Display Properties
Output:


File (Export Table to ASCII File)



Table Copy to Clipboard



Table Print

• Table Print Preview
Columns:
See the Glossary for information regarding the definitions of the columns in the Table window.
Use the Scenario control located at the top of the Table Window to quickly view the data for
different scenarios.
To access the Table window, open the Table Manager, highlight the table you wish to open, and click
OK.

7.4.1

Editing Tables
Editable Table Columns
Editable table columns correspond to input data that you can change. The values in these columns can be
modified either directly or through the Global Edit option. These columns are displayed with a white
background.
Non-editable table columns are displayed with a yellow background, and correspond to model results
calculated by the program and composite values.

Table Navigation
The Table window supports two modes: Table Navigation Mode and Cell Navigation Mode. By pressing
the F2 key, you can toggle between them.
Table Navigation Mode
The Arrow keys, Home, End, PgUp, PgDn, Ctrl+<arrow> keys navigate to different cells in a table. Table
Navigation Mode is the default mode when editing a table. To edit within a single cell of a table, press the
F2 key to switch to Cell Navigation Mode.

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Cell Navigation Mode (Edit Mode)
In Cell Navigation Mode, the Arrow keys, Home, and End keys navigate within a single cell. When Cell
Navigation Mode is active, the word "EDIT" will appear on the status pane at the bottom of the window.
Cell Navigation Mode will automatically terminate when you press any key except for Left, Right, Home,
End, Delete, or Backspace.

Globally Editing Data
You can globally change the values of any editable column in a table. Right-click the column that you
wish to globally change and choose the Global Edit menu item.
For numeric columns:
1.

Choose the operation to be performed: Add, Divide, Multiply, Set, or Subtract.

2.

Enter the value you wish to use.

3. Click OK, and the values in the entire column will be updated to reflect this change.
For non-numeric columns:
1.

Enter the new value.

2.

Click OK, and the values in the entire column will be updated to reflect this change.

Global Edit is available only for editable columns. Global Edit is not available in 2-row tables
(in SewerCAD or StormCAD). You can use Global Edit in conjunction with Filtering to globally
edit a subset of elements.

7.4.2

Sorting/Filtering Tables
Sorting Tables
Tables can be sorted based on a single column, multiple columns, or network order.

Sort By Network
In a network-based sort, elements in the table will be sorted so that structures furthest from the outlet will
appear at the top of the list, and structures closest to the outlet will appear at the bottom of the list.
"Furthest from the outlet" as used here does not refer to an actual distance, but to the number of
pipes that are between the specified element and the outlet. If your system contains multiple
networks, the elements in the first network will be sorted as described above, followed by the
elements in the second network, and so on.

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Custom Sort
You can sort elements in the table based on one or more columns, in ascending or descending order. For
example, the following table is given:
Slope (ft/ft)

Depth (ft)

Discharge (cfs)

0.001

1

4.11

0.002

1

5.81

0.003

1

7.12

0.001

2

13.43

0.002

2

19.00

0.003

2

23.27

A custom sort is set up to sort first by Slope, then by Depth, in ascending order. The resulting table would
appear in the following order:
Slope (ft/ft)

Depth (ft)

Discharge (cfs)

0.001

1

4.11

0.001

2

13.43

0.002

1

5.81

0.002

2

19.00

0.003

1

7.12

0.003

2

23.27

To access the custom sort capability, open the table you wish to sort. Then, right-click a column label and
select Sort / Custom.

Filtering Tables
To access the filtering operations, use the Options button at the top of the Table window (in the case of a
FlexTable), or right-click the column header by which you wish to filter. Filters allow you to change the
table so only rows that match the specified criteria will appear.


Quick Filter - Set up a simple filter by right-clicking the column by which you wish to filter.



Custom Filter - Set up a custom filter based on one or more criterion.



Reset - Turn off the active filter, causing all available rows in the table to be displayed.
Another way to select which elements are displayed in the table consists of first selecting
elements, either graphically, or by using the Selection Set tool. Then, right-click any of the
selected elements and choose Edit Group from the pop-up menu that appears. This will display
the Table Manager dialog. Only the selected elements will appear in any of the tables you open
at this point.

When you perform a Quick Filter or a Custom Filter, the Filter dialog will open allowing you to specify
your filtering criterion.
Each filter criterion is made up of three items:

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Column - The attribute to filter.



Operator - The operator to use when comparing the filter value against the data in the specific column
(operators include: =, >, >=, <, <=, <>).

• Value - The comparison value.
Any number of criterion elements can be added to a filter. Multiple filter criterion are implicitly joined
with a logical "AND" statement. When multiple filter criterion are defined, only rows that meet all of the
specified criteria will be displayed. A filter will remain active for the associated table until the filter is
reset.
The status pane at the bottom of the Table window always shows the number of rows displayed and the
total number of rows available (e.g. "10 of 20 elements displayed"). When a filter is active, this message
will appear in a highlighted color.
Table filtering allows you to perform global editing on any subset of elements. Only the elements that
appear in the filtered table will be edited.

7.4.3

Table Customization
There are several ways to customize tables to meet a variety of output requirements:


Changing the Report Title - When you print a table, the table name is used as the title for the printed
report. You can change the title that appears on your printed report by renaming the table, using the
Table Manager.



Adding/Removing Columns - You can add, remove, and change the order of columns by using the
Table Setup dialog. Use the Table Manager to access the Table Setup dialog.



Drag/Drop Column Placement - With the Table window open, select the column that you would like
to move by holding down the left mouse button on its column heading. Drag the column heading to
the left or right, and release the mouse button to drop the column into its new location.



Resizing Columns - With the Table window open, place your pointer over the vertical separator line
between column headings. Notice that the cursor changes shape to indicate that you can resize. Hold
down the left mouse button and drag the mouse to the left or right to "stretch" the column to its new
size. When you are satisfied, release the mouse button to set the new column width.



Changing Column Display Properties - With the Table window open, right-click in the heading area
of the column you wish to change and choose the Properties menu item. The current column
properties will be displayed in the Set Field Options dialog. Refer to the section on Local Units for
additional information.



Changing Column Headings - With the Table window open, right-click the column heading that you
wish to change and choose Edit Column Label. Refer to section on Changing Column Headings for
additional information.

Changing Column Headings
To change the label of any column in the Table window, right-click the column heading that you wish to
change and choose Edit Column Label from the context menu. The backslash character (\) can be used to
insert a line-break wherever you want the title to be split into multiple lines. If you enter an empty label,
the column heading will be restored to the default label.

Abbreviated Labels
Using label abbreviations will allow columns to take up less space. This will permit more data to fit on
each page when printing a report. If you wish to define an abbreviated label, right-click the desired column
heading and choose Edit Column Label. In the Label dialog, separate the abbreviated label from the
default label with the '|' symbol, located above the backslash (\) on most keyboards. For example, to use

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125

the abbreviation L for the Length column, type Length|L in the field provided. When the Use Label
Abbreviations option is toggled on, the abbreviated label will appear.
To toggle the Use Label Abbreviations option on and off, select Options / Use Abbreviated Labels from
the Table window.

Changing Column Display Properties
You can change the display properties (e.g. units, precision) of any numeric column in the Table window.
Right-click the label of the column that you wish to change, and select Properties from the pop-up menu.
This opens the Set Field Options dialog, where you can change the display properties of the column.

Local vs Synchronized Units
Use the Options button at the top of the Table window to access the Use Local Units menu item. Click
the menu item to toggle between Local Units and Synchronized Units. A check mark will appear next to
the Use Local Units menu item to indicate that Local Units mode is active. Otherwise, Synchronized Units
mode is active.


Synchronized Units - This is the default mode that allows the table to stay synchronized with the
active project. If you have one project in US Customary and one project in SI units, the Table will
match the units in the project that is currently open.



Local Units - Local Units mode allows the table to maintain its own "local" set of column properties
(units, precision, etc). This is a powerful feature that gives you the ability to build tables that are
always in a fixed unit system, no matter what unit system the active project is currently using. This is
useful for printing reports in different unit systems.
When the Table window is open, the current unit synchronization mode is displayed in the status pane at
the bottom of the window.

Mixing Units in a Tabular Report
This software allows for duplicate columns in a table, thus giving you the ability to display an attribute in
different units.
For example, to see two "Pipe Length" columns in a Table, one in feet and one in meters:
1.

Open the Table Manager.

2.

Click the Table Management button, and select New to create a new table.

3.

Select the Pipe Table Type from the choice list, and enter a name for your new table. Click OK
and you will be taken to the Table Setup dialog where you can customize your table.

4.

In the Table Setup dialog, activate the Allow Duplicate Columns check box located at the lower
left corner of the dialog.

5.

Add the Length column to the Selected Columns list.

The Length column will still appear in the Available Columns list, but will be displayed in a
lighter color, indicating that it has already been selected.
6.

Add the Length column again.

7.

Click OK to close the Table Setup dialog. From the Table Manager, highlight the table you
have just created, and click OK.

8.

Click the Options button at the top of the window and select the Use Local Units menu item to
turn Local Units on. You will be prompted to verify that you want to use local units. Click Yes.

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9.

7.4.4

Right-click the first Length column and select Length Properties to set the units in the column
to "ft." Then, right-click the second Length column to set the units to "m."

Table Output
Table Copy to Clipboard
The Copy button at the top of the Table window allows you to copy tab delimited data to the Windows
clipboard. Tab delimited data can be pasted directly into your favorite spreadsheet program or word
processor.

Table Print
The Print button at the top of the Table window is used to output the table directly to the printer.

Table Print Preview
Click the Print Preview button at the top of the Table window to view the report in the format that will be
printed.
Using label abbreviations will allow some columns to be narrower, permitting more data to fit on
each page. Use the Options button at the top of the Table window to access this option.
Printing with landscape orientation will also allow more columns to fit on a single page. From
the Print Preview window, use the Options / Print Setup menu item to access orientation.
Clicking the Copy button will allow you to paste the formatted information into another
application such as Microsoft Word.

File (Export Table to ASCII File)
You may export the data shown in the Table window to an ASCII text file in either tab or commadelimited format.
To export a table to an ASCII File format, select File / Export Data and either Tab Delimited or Comma
Delimited from the Table window.

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Chapter 8
Scenarios and Alternatives
8.1 Overview
The scenario management feature allows you to easily analyze and recall an unlimited number of "What
If?" calculations for your model. The powerful two-level design, which uses Scenarios that contain
Alternatives, gives you precise control over changes to the model, while eliminating any need to input or
maintain redundant data.
We have worked hard to devise a system that offers the power and flexibility that you demand, with the
ease of use that you have come to expect from us. If you are like most users, you will want to jump right in
without having to spend a lot of time reading. When you are ready to create your first scenario, you will
find that you will be able to accomplish what you want easily and quickly.
The Scenario Wizard is designed to get you started quickly, while slowly exposing you to the power
behind scenarios and alternatives.
When you are ready to model more complex scenarios, you will appreciate the power and flexibility
provided by the various scenario management features.
If you are a beginning user, try the Scenario Wizard and run the Scenario tutorial. Also, refer to the
Scenario Management Reference Guide in Appendix D. Be sure to read about Alternatives, and investigate
the Alternatives Manager dialog.

8.2 Alternatives
Alternatives are the building blocks behind scenarios. They are categorized data sets that create scenarios
when placed together. Alternatives hold the input data in the form of records. A given record holds the
data for a particular element in your system. The different types of alternatives are as follows:


Physical Properties



Sanitary (Dry Weather) Loading



Infiltration and Inflow Loading



Known Flow Loading



Structure Headlosses



Boundary Conditions



Design Constraints



Initial Settings



Operational



Cost



User Data

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Chapter 8 - Scenarios and Alternatives

The exact properties of each alternative are discussed in their respective sections. By breaking up
alternatives into these different types, we give you the ability to mix and match different alternatives within
any given scenario.
Scenarios are composed of alternatives, as well as other calculation options, allowing you to compute and
compare the results of various changes to your system. Alternatives can vary independently within
scenarios, and can be shared between scenarios.
There are two kinds of alternatives: Base alternatives and Child alternatives. Base alternatives contain
local data for all elements in your system. Child alternatives inherit data from base alternatives, or even
other child alternatives, and can contain data for one or more elements in your system. The data within a
child alternative consists of data inherited from its parent and the data altered specifically by you (local
data).
When you first set up your system, the data that you enter is stored in the various base alternatives. If you
wish to see how your system will behave, for example, by increasing the diameter of a few select pipes,
you can create a child alternative to accomplish that. You can make another child alternative with even
larger diameters, and another with smaller diameters. There is no limit to the number of alternatives that
you can create.
Scenarios allow you to specify the alternatives you wish to analyze. Once you have determined an
alternative that works best for your system, you can permanently merge changes from the preferred
alternative to the base alternative if you wish.
Remember that all data inherited from the base alternative will be changed when the base alternative
changes. Only local data specific to a child alternative will remain unchanged.

8.2.1

Alternatives Manager
The Alternatives Manager is a central location for managing all of the alternatives in your project.
Across the top of the alternative manager are tabs for each type of alternative. The tabs access a tree view
of the available alternatives of the following tabs:


Physical Properties



Sanitary (Dry Weather) Loading



Infiltration and Inflow Loading



Known Flow Loading



Structure Headlosses



Boundary Conditions



Design Constraints



Initial Settings



Operational



Cost

• User Data
On the right side of the dialog are a number of buttons that provide functions for managing the alternatives.
The following list provides a brief description of the function of each of these buttons:


Add - Create a new base alternative, first prompting for a name, then opening an Alternatives Editor.
Base alternatives are initialized with the data that is currently entered either in tables or specific
element dialogs.

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129



Add Child - Create a new child alternative that inherits data from the selected parent alternative. This
allows you to automatically share the majority of the records with a parent alternative, while modifying
only selected records in the child alternative.



Edit - Open the tabular record editor for the selected alternative. This tabular record contains the
values that are used by the selected alternative.



Merge - Move all records from the selected child alternative into its parent alternative, and then
remove the selected alternative. The records in the selected alternative will replace the corresponding
records in the parent. This is helpful when you have been experimenting with changes in a child
alternative, and you want to permanently apply those changes to the parent alternative. All other
alternatives that inherit data from that parent alternative will reflect these changes.



Rename - Rename an existing alternative. This invokes an in-place editor in the tree view of the
available alternatives. Make the desired changes to the existing name, and press the Enter key



Duplicate - Create a new alternative filled with records copied from the selected alternative. Use this
if you wish to copy the data from an alternative but not create a child. The two alternatives will be
independent.



Delete - Remove the selected alternative and its records. Deleting an alternative will also delete all of
the input data associated with that alternative. You cannot delete an alternative that has children
associated with it.



Report - Generate a Print Preview of a summary report of the selected alternative, all alternatives, or
the selected alternative and all of its children in that hierarchy.
You will not be allowed to merge or delete an alternative that is referenced by one or more
scenarios. When you attempt to perform the operation, you will be provided with a list of the
scenarios that reference the alternative.
If you are attempting to merge an alternative that is referenced, you will need to edit the
scenario(s) that references the alternative you are merging, and make them reference the parent
alternative to which you are merging. Use the Scenario Manager window to edit the scenario(s),
and the Alternatives tab to make the scenario point to the parent alternative.

8.2.2

Alternatives Editor
The Alternatives Editor displays all of the records held by a single alternative. These records contain the
values that are active when a scenario referencing this alternative is active. They allow you to view all of
the changes that you have made for a single alternative. They also allow you to eliminate changes that you
no longer need.
There is one editor for each alternative type. Each type of editor works basically the same, and allows you
to make changes to a different aspect of your system. The first column contains check boxes, which
indicate the records that have been changed in this alternative.


If the box is checked, the record on that line has been modified and the data is local, or specific, to this
alternative.



If the box is not checked, it means that the record on that line is inherited from its higher-level parent
alternative. Inherited records are dynamic. If the record is changed in the parent, the change will be
reflected in the child. The records on these rows reflect the corresponding values in the alternative’s
parent.

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As you make changes to records, the check box will automatically become checked. If you want
to reset a record to its parent's values, simply uncheck the corresponding check box.
Many columns support Global Editing, allowing you to change all values in a single column.
Right-click a column header to access the Global Edit option.
The checkbox column will be disabled when you edit a base alternative.
To access the Alternatives Editor for a particular alternative, select Analysis\Alternatives from the pulldown menu to activate the Alternatives Manager. Select the desired alternative tab, choose the alternative
you would like to edit, and click the Edit button.

8.2.3

Physical Properties Alternative Editor
The Physical Properties Alternative Editor allows you to modify the physical properties of any network
element, including gravity pipes, pressure pipes, manholes, junction chambers, pressure junctions, pumps,
and wet wells.

Physical Properties Alternative Editor for Gravity Pipes
The Physical Properties Alternative Editor for gravity pipes is used to create various data sets for the
physical characteristics of gravity pipes. The following properties are available for editing:


Set Invert to Upstream Structure - Specifies whether if the invert will be entered by the user or
calculated using upstream structure sump elevation and desired sump depth.



Upstream Invert Elevation - Elevation for the upstream invert.



Set Invert to Downstream Structure - Specifies whether if the invert will be entered by the user or
calculated using downstream structure sump elevation and desired sump depth.



Downstream Invert Elevation - Elevation for the downstream invert.



Section Shape - Shape of a pipe.



Material - Type of material of which a pipe is made. The available pipe materials are contained in the
Material Engineering Library. The Material Library allows you to create new materials and
customize existing ones.



Roughness Coefficient - Specify a roughness coefficient for a pipe based on the pipe material
selected, or enter a unique value.



Section Size - Specify new dimensions for a particular pipe segment. The available dimensions for a
particular section shape are contained in the Section Size Library. You may add new values to this
library if the desired size is not available.



Number of Sections - Specify the number of pipe sections.



User-Defined Bend Angle - Choose to either enter a bend angle or accept the bend angle calculated by
the program from the graphical layout.



Bend Angle - Specifies the bend angle of the pipe. If the User Defined Bend Angle box is checked,
the field is editable.

Physical Properties Alternative Editor for Pressure Pipes
The Physical Properties Alternative Editor for pressure pipes is used to create various data sets for the
physical characteristics of pressure pipes. The following properties are available:

Chapter 8 - Scenarios and Alternatives

131



Upstream Invert Elevation - Elevation for the upstream invert.



Downstream Invert Elevation - Elevation for the downstream invert.



Set Invert to Downstream Structure - Specifies whether if the invert will be entered by the user or
calculated using downstream structure sump elevation and desired sump depth.



Material - Type of material of which a pipe segment is made. The available pipe materials are
contained in the Material Engineering Library. The Material Library allows you to create new
materials and customize existing ones.



Diameter - Inside diameter of the pipe.



Roughness - Measure of the pipes’ internal roughness based on the pipe material selected, or enter a
unique value.



Minor Loss Coefficient - Appurtenances such as valves, bends, and tees contribute to local flow
disturbances resulting in energy loss. Minor losses can be entered in one of three ways:





Manually enter a value for the minor loss.



Select a minor loss from the existing list. When you click the minor loss field, a choice list
will appear. Click this to access the Minor Loss Coefficients that are stored in the Minor
Loss Library.



Create a composite minor loss. When you click a minor loss field, an ellipsis (…) button will
appear. Click this to access the Minor Loss Elements Editor. Here you can specify the
quantity of a particular type of minor loss. If you need a minor loss that is not available, click
the ellipsis (…) button to access the Minor Loss Library. You can edit existing minor losses
or create new ones. Use the Minor Loss Elements Editor to enter as many types of minor
losses as you need.

Check Valve - A check box you can mark to indicate the presence of a check valve.

Physical Properties Alternative Editor for Manholes
The Physical Properties Alternative Editor for manholes is used to create various data sets for the
physical characteristics of manholes. The following properties are available:


Ground Elevation - Ground elevation at the manhole.



Sump Elevation - Elevation of the manhole sump.



Set Rim Equal to Ground Elevation - Specify whether the ground elevation should be set equal to
the rim elevation of the manhole. If the box is checked, the rim elevation will be automatically set
equal to the ground elevation. Otherwise, the rim elevation will be user-defined.



Rim Elevation - Specify the elevation of the rim if the box in the column labeled Set Rim Equal to
Ground Elevation is not checked. If it is checked, the rim elevation is automatically set equal to the
ground elevation.



Bolted Cover - Specify whether the manhole cover is bolted. If the cover is not bolted and the
Hydraulic Grade is determined to be above the rim or ground elevation, whichever is higher, the model
will report a surcharged condition and the Hydraulic Grade will be reset to the higher of the rim and
the ground elevation for the next calculation. If the cover is bolted and the Hydraulic Grade is
determined to be above the ground or rim elevation, it will NOT be reset.



Has Diversion - Determines if this element diverts flows out of the network or not. If this box is
checked, the user will be able to edit diversion properties.



Diversion Target - Determines the destination for diverted flows. To edit this field, the Has
Diversion box must be checked.

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Diversion Rating Table - Editor button for Diversion Rating Curve Table. To edit this field, the Has
Diversion box must be checked.



Structure Diameter - Diameter of the manhole structure.

Physical Properties Alternative Editor for Junction Chambers
The Physical Properties Alternative Editor for junction chambers is used to create various data sets for
the physical characteristics of junction chambers. The following properties are available:


Ground Elevation - Ground elevation at a junction chamber.



Top Elevation - Top elevation of a junction chamber.



Bottom Elevation - Bottom elevation of a junction chamber.



Has Diversion - Determines if this element diverts flows out of the network or not. If this box is
checked, the user will be able to edit diversion properties.



Diversion Target - Determines the destination for diverted flows. To edit this field, the Has
Diversion box must be checked.



Diversion Rating Table - Editor button for Diversion Rating Curve Table. To edit this field, the Has
Diversion box must be checked.



Structure Diameter - Diameter of the junction structure. For non-circular junction chambers, an
equivalent diameter should be entered.

Physical Properties Alternative Editor for Wet Wells
The Physical Properties Alternative Editor for wet wells is used to create various data sets for the
physical characteristics of wet wells. The following properties are available:


Ground Elevation - Ground elevation at a wet well.



Base Elevation - Elevation of the base of the wet well.



Minimum Elevation - Lowest possible water surface elevation for the wet well. This elevation must
be above the base elevation.



Maximum Elevation - Highest possible water surface elevation for the wet well.



Section - Physical parameters that define the wet well cross sectional geometry. There are two types
of wet well sections, Constant Area and Variable Area. Click this field, then click the ellipsis (…)
button that appears. This will activate a dialog allowing you to edit the parameters for the active wet
well section type.

Physical Properties Alternative Editor for Pumps
The Physical Properties Alternative Editor for pumps is used to create various data sets for the physical
characteristics of pumps. The following properties are available:


Elevation - Elevation of the center of the pump.



Pump Type - Attributes that define the pump's operating characteristics. Click this field, then click
the ellipsis (…) button that appears. This will activate a dialog allowing you to edit the parameters for
the active pump type.

Physical Properties Alternative Editor for Pressure Junctions
The Physical Properties Alternative Editor for pressure junctions is used to create various data sets for
the physical characteristics of pressure junctions. The following property is available:


Ground Elevation - Ground elevation at a pressure junction.

Chapter 8 - Scenarios and Alternatives

133

Physical Properties Alternative Editor for Outlets
The Physical Properties Alternative Editor for outlets is used to create various data sets for the physical
characteristics of outlets. The following properties are available:

8.2.4



Ground Elevation - Ground elevation at the outlet.



Sump Elevation - Elevation of the outlet sump.



Set Rim Equal to Ground Elevation - Specify whether the ground elevation should be set equal to
the rim elevation of the outlet. If the box is checked, the rim elevation will be automatically set equal
to the ground elevation. Otherwise, the rim elevation will be user-defined.



Rim Elevation - Specify the rim elevation if the box in the column Set Rim Equal to Ground
Elevation is not checked. If the box is checked, the rim elevation is automatically set equal to the
ground elevation.

Sanitary (Dry Weather) Loading Alternative Editor
The Sanitary (Dry Weather) Loading Alternative Editor allows you to edit the sanitary (dry weather)
loads at manholes, pressure junctions, and wet wells. Sanitary loads, which comprise the base load of the
sewer system, are loads produced by residential, commercial, recreational, and industrial activities.
The tabbed dialogs for manholes, pressure junctions, and wet wells all follow the same format.
The alternative contains the following columns:


Sanitary Load Type - Identifies the type of load: Base Load, Pattern Load, or Hydrograph if there
is a single load associated with the node. If there are multiple loads associated with the node then the
Load Description will display Composite. By clicking a Load Description cell in the table, a button
will be displayed. Click this button to access the Composite Sanitary Load dialog. From this dialog
you can edit each of the individual loads.



Sanitary Unit Load Type - Select the unit load type as established in the in the Unit Sanitary Load
Engineering Library. If multiple sanitary unit loads are associated to the node then the field will
display Composite.



Sanitary Unit Load Count - Specify the number of loading units. If multiple sanitary unit loads are
associated to the node then the field will display N/A.



Sanitary Unit Load Units - Displays the loading units associated with the sanitary unit load type. For
example, if the unit load type is "Apartment" the actual unit per a quantity of flow could be "Resident."
If there is more than one unit loads associated with the elements the field will display N/A.



Sanitary Pattern Load Base Flow - Enter a single load associated with the Sanitary Pattern. If
multiple pattern loads are associated with the structure then this field will display the sum of all the
sanitary base loads.



Sanitary Pattern Load Pattern - Select the pattern, which describes how the Sanitary Base Load
varies over time. If multiple pattern loads are associated with the node then the Sanitary Pattern field
will display Composite. Click the ellipses (…) button in the field (if editable) to open up the Pattern
Manager.

Sanitary Load Composite Dialog
The Sanitary Load Composite dialog allows you to apply an unlimited number of different sanitary loads
to a single node.
The following operations can be performed on the Sanitary Flow list in the section:


Add - Add a new load to the Sanitary Flow list.

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Chapter 8 - Scenarios and Alternatives
Edit - Opens the editor for an existing load in the list.

• Delete - Deletes a sanitary load from the list.
The Sanitary (Dry-Weather) Flow section is specified as a collection of sanitary loads applied to the
selected node. The following types of loads can be applied:

8.2.5



Hydrograph - A flow vs. time distribution



Unit Load - The type of Unit Load and the number of units associated with Unit Load. For example,
5000 passengers at an Airport.



Pattern Load - A direct, known sanitary load with a set pattern.

Infiltration and Inflow Loading Alternative Editor
The Infiltration and Inflow Loading Alternative Editor allows you to edit the wet weather loads at
gravity pipes, manholes, and wet wells. Wet weather loads are those produced by the introduction of
rainfall water into the sewer system through groundwater infiltration or rainfall inflow.
Groundwater infiltration, which occurs along gravity pipes, is specified on the Gravity Pipe tab of the
Infiltration and Inflow Loading Alternative Editor. Inflow, which occurs at manholes and wet wells, is
specified on the Inflow Structure tab.

Infiltration and Inflow Loading Alternative Editor for Gravity Pipes
The Infiltration and Inflow Loading Alternative Editor for gravity pipes is used to specify the
infiltration type and any additional infiltration for each gravity pipe individually. The following columns
are available:


Infiltration Load Type - Select how the direct infiltration along a gravity pipe will be computed.
Click this field and a choice list will appear. Choose from the list of the available infiltration types.
Once you have selected an infiltration type you can click the ellipses (…) button to bring up a dialog to
edit data related to that infiltration type. For example, if Hydrograph is selected, clicking the ellipses
(…) button will allow you input the associated flow vs. time data.



Infiltration Loading Unit - Specify the unit used to define infiltration rates.



Infiltration Rate per Loading Unit - Specify the rate of infiltration for the selected loading unit and
infiltration type.



Infiltration Unit Count - Editable when Count Based is selected as the Infiltration Type.



Base Flow - Editable when Pattern Load is selected as the Infiltration Type.



Pattern - Editable when Pattern Load is selected as the Infiltration Type. Click the ellipses (…)
button in the field (if editable) to open up the Pattern Manager.



Infiltration Additional Flow - Specify a lump sum infiltration amount for each gravity pipe. The
total infiltration into a single gravity pipe is the sum of the direct additional infiltration.

Infiltration and Inflow Loading Alternative Editor for Inflow Structures
The Infiltration and Inflow Loading Alternative Editor for inflow structures is used to specify the list of
wet weather inflow loads into manholes and wet wells. The following columns are available:


Inflow Load Type - The column will display Hydrograph or Pattern Loads if there is a single load
of that type associated with node. Otherwise, if multiple inflow loads are associated with the node, the
column will display Composite. To access the Composite Inflow dialog, click a cell in the Inflow
Load Description column. A button will appear. Click on this button to bring up the Composite
Inflow dialog.

Chapter 8 - Scenarios and Alternatives

135



Inflow Pattern Load Base Load - Enter a single load associated with the Inflow Base Pattern. If
multiple pattern loads are associated with the structure then this field will display the sum of all the
inflow base loads.



Inflow Patten Load Pattern - Select the pattern, which describes how the Inflow Base Load varies
over time. If multiple pattern loads are associated with the node then the Inflow Pattern field will
display Composite. Click the ellipses (…) button in the field (if editable) to open up the Pattern
Manager.

Composite Inflow Dialog
The Composite Inflow dialog allows you specify the Inflow loading for structure in the Infiltration and
Inflow Loading Alternative.
The following operations can be performed on the Inflow list in the section:


Add - Add a new load to the Inflow list.



Edit - Opens the editor for an existing load in the list.

• Delete - Deletes an inflow load from the list.
The Inflow section is specified as a collection of wet weather loads applied to the selected node. The
following types of loads can be applied.

8.2.6



Hydrograph - A flow vs. time distribution



Pattern Load - A direct, known wet weather load with a set pattern.

Known Flow Loading Alternative Editor
The Known Flow Loading Alternative Editor allows you to specify known flows at individual manholes
and wet wells. Both the Manhole and Wet Well tabs are identical.
Known flows are a special type of fixed load. They remain constant as they progress downstream, and
combine directly as a simple sum, similar to additional loads. During a Steady-State analysis when a
known flow is specified at a downstream manhole or wet well, the local known flow replaces the upstream
known flow rather than being added directly to the upstream known flow. During an Extended Period
Simulation known flows generate constant load hydrographs which are additive. Known Flows do not
replace each other during an Extended Period Simulations.

8.2.7

Structure Headlosses Alternative Editor
The Structure Headlosses Alternative Editor allows you to change the method used to calculate the
headloss through each manhole and junction chamber. Both the manhole and the junction chamber tabs are
identical. The available methods are:


Absolute



Standard



HEC-22 Energy



AASHTO

• Generic
For further information on these methods, see Appendix B.

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Chapter 8 - Scenarios and Alternatives

Boundary Conditions Alternative Editor
The Boundary Conditions Alternative Editor gives you the ability to modify the tailwater condition and
tailwater elevation at the outlets. You can specify free outfall, crown, or user-specified tailwater elevation.
The program determines the tailwater elevation for all the options except user-specified.

8.2.9

Design Constraints Alternative Editor
The Design Constraints Alternative Editor allows you to edit the gravity pipe and gravity structure
constraints governing the design of the system. It also allows you to specify which gravity elements you
want designed, and the extent to which you want them designed. For example, you may want to design a
particular pipe. However, you may only want to design the downstream invert elevation to meet a
particular velocity, cover, and slope constraint. The Design Constraints Alternative Editor allows you to
accomplish this.
The tabbed dialog for each particular type of element follows the same general format. The top of the
dialog box contains several fields where the default design constraints can be entered. The constraints
entered in these fields are applied to every element in the table on the bottom of the dialog, except the
elements that are specified to contain local values. This system allows you to rapidly enter the values that
govern most of the elements in the table, then manually override the constraints for those elements that are
exceptions to the majority.
In order to specify that an element contains local data, place a check mark in the column labeled Specify
Local Constraints on the same row as the element. The local design constraints, if specified, will override
the default design constraints during an automatic design for that particular element. When the check mark
appears, the yellow columns that display the global design constraints defined in the top of the dialog will
turn white on the row of the element that is being modified. This means that you can now change the
design constraint values for this particular element. If you click the check mark again, the opposite
happens. The columns containing the constraints turn yellow and revert to the global values entered in the
top of the dialog. The following tabs are available:


Gravity Pipe

• Gravity Structure
Additional check boxes are available to specify exactly what you want the software to design
automatically.

Design Constraints Alternative Editor for Gravity Pipes
This dialog contains the following sections:




Minimum and Maximum Default Constraints


Minimum Velocity - Minimum velocity that is allowed in a pipe.



Minimum Cover - Minimum depth to which the crown of a pipe must be buried.



Minimum Slope - Minimum slope of a pipe segment.



Maximum Velocity - Maximum velocity that is allowed in a pipe.



Maximum Cover - Maximum depth to which the crown of a pipe may be buried.



Maximum Slope - Maximum slope of a pipe segment.

Extended Design


Part Full Design - Specify what percent capacity you want to design your gravity pipes to.
In other words you can specify that you want your pipes to be designed for 50% capacity.
Click on the check box adjacent to the Part Full Design label and then enter the desired
percentage. This value will show up for every pipe in the system. You can then manually
adjust specific values in the table on the bottom half of this dialogue.

Chapter 8 - Scenarios and Alternatives



137



Allow Multiple Sections - Specify whether the automatic design should consider the use of
multiple parallel pipes, and if so how many. By default the model will only use one pipe
section for design.



Limit Section Size - Specify a maximum section size for design.

Table Columns - The following columns are editable:


Design Pipe - Specify whether the program should design the pipe based on the constraints
given to the model.



Design Upstream Invert - Specify if the program should design the upstream invert based on
the constraints given in the model.



Design Downstream Invert -Specify if the program should design the downstream invert
based on the constraints given in the model.



Specify Local Constraints - If the box in this column is checked then you can enter local
values to replace the default values. If there is not a check mark in the box then the program
will automatically use the default constraints.

The rest of the columns contain the values entered in the Default Constraints section, unless the
Specify Local Constraints box is checked. These are the constraints that govern the automatic design
process:


Minimum Velocity



Maximum Velocity



Minimum Cover



Maximum Cover



Minimum Slope



Maximum Slope

The next six columns are for specifying local values for the Extended Design Options discussed above:


Part Full Design



Design Percent Full



Allow Multiple Sections



Maximum Number Sections



Limit Section Size



Maximum Design Section Rise

For example, to specify a percentage full for a particular pipe, check the appropriate box in the column
entitled Part Full Design. Then type in the value in the next column entitled Design Percent Full.

Design Constraints Alternative Editor for Gravity Structures
This dialog contains the following sections:


Default Design Constraints


Pipe Matching - Specify whether the program should match pipe crowns or inverts.



Matchline Offset - This is used to design invert elevations in and out of a gravity structure.
The specified value will produce a corresponding drop between the upstream and downstream

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Chapter 8 - Scenarios and Alternatives
invert elevations. A drop such as 0.1 ft is typically used to compensate for the junction
headloss.




Allow Drop Structure - Permit the program to use drop structures in design mode. If the box
next to this label has a check mark then drop structures are permitted; otherwise they are not
permitted.

Table Columns


Structure Type - Specify if the structure is a junction chamber, manhole, or outlet.



Design Structure Elevation - Specify whether the sump elevation can be adjusted. If there is
a check mark in the cell in this column then you can set the sump elevation of this node,
otherwise the program will calculate the sump elevation.



Desired Sump Depth - Set the sump depth if there is a check mark in the column labeled
Design Structure Elevation. If there is not a check mark in this column then the program
will use the sump depth entered in the respective node dialog.



Local Pipe Matching Constraints - Assign local values to the design constraints for a node
if there is a check mark in the box in this column. If there is not a check mark then the
program assigns the default constraints to the node.

The values in the following columns are the same as the default constraints if there is not a check mark
in the column labeled Local Pipe Matching Constraints. If there is a check mark, you may enter local
data.

8.2.10



Pipe Matching



Matchline Offset



Allow Drop Structure.

Initial Settings Alternative Editor
The Initial Settings Alternative Editor allows you to specify the starting conditions of pressure pipes,
pumps, and wet wells. For example, you can specify whether a particular pressure pipe is open or closed.
Thereby modeling how the system will react if a certain pipe goes out of service, or if you wish to isolate
future portions of the system.

Initial Settings Alternative Editor for Pressure Pipes
The Initial Settings Alternative Editor for pressure pipes is used to specify if pressure pipes are initially
open or closed.

Initial Settings Alternative Editor for Pumps
The Initial Settings Alternative Editor for pumps allows you to specify the initial pump settings. The
fields for each pump are as follows:


Status - Indicates whether the pump is initially On or Off.



Relative Speed Factor - Specify the initial speed of the pump impeller relative to the speed at which
the pump curve is defined.

Initial Settings Alternative Editor for Wet Wells
The Initial Settings Alternative Editor for wet wells allows you to specify the initial wet well settings.
The fields for each wet well are as follows:

Chapter 8 - Scenarios and Alternatives

8.2.11



Fixed Level - Determine how the Hydraulic grade in the wet well is calculated. See the Hydraulic
Transition from Gravity to Pressure Network topic in Appendix B for more details.



Initial Elevation - The elevation or level of the water surface at the beginning of the simulation.

139

Operational Alternative Editor
The Operational Alternative Editor allows you to specify controls on pressure pipes and pumps. The
Controlled field contains a true or false statement that indicates whether the network element is controlled.
Clicking this field activates a button that allows you to edit the controls for the network element.

8.2.12

Cost Alternative Editor
One of the most common uses of the Cost Manager is to compare the cost between several different
system configurations. The compartmentalization of the data afforded by the cost alternative makes it easy
to develop and subsequently compare various cost data sets. Developing multiple cost alternatives is an
effective way to evaluate the cost of several different proposed solutions or to separate the costs associated
with several phases of construction.
The cost alternative editor contains a tab for each type of element. Each tab contains the following fields
for editing the cost data associated with an element.

8.2.13



Label - Identifies the element associated with a particular record.



Include in Cost Calculation - This field allows the user to specify whether or not to include
the element in the cost calculation. If this field is check the item will be included in the cost
calculation.



Element Costs - This field is only enabled when the field Include in Cost Calculation has a
check mark. If this field is editable you can click on it to open up a dialog where you can edit
the construction and non-construction costs associated with an element. Note that you can
Global Edit this field to edit the construction and non-construction costs of all the elements in
the alternative.

User Data Alternative Editor
The User Data Alternative Editor allows you to edit the user data you defined in the User Data Extension
command for each of the network element types. The User Data Alternative Editor contains a tab for
each type of network element.
See the section Hydraulic Element Editors in the help for more information.

8.3 Scenarios
A Scenario contains all the input data (in the form of Alternatives), calculation options, results, and notes
associated with a set of calculations. Scenarios let you set up an unlimited number of "What If?" situations
for your model, and then modify, compute, and review your system under those conditions.
You can create scenarios that reuse or share data in existing alternatives, submit multiple scenarios for
calculation in a batch run, switch between scenarios, and compare scenario results - all with a few mouse
clicks. There is no limit to the number of scenarios that you can create.
There are two types of scenarios:


Base scenarios - Contain all of your working data. When you start a new project, you will begin with
a default base scenario. As you enter data and calculate your model, you are working with this default
base scenario and the alternatives it references.

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Chapter 8 - Scenarios and Alternatives
Child scenarios - Inherit data from a base scenario, or other child scenarios. Child scenarios allow
you to freely change data for one or more elements in your system. Child scenarios can reflect some or
all of the values contained in their parent. This is a very powerful concept, giving you the ability to
make changes in a parent scenario that will trickle down through child scenarios, while also giving you
the ability to override values for some or all of the elements in child scenarios.

The calculation options are not inherited between scenarios, but are duplicated when the
scenario is first created. The alternatives and data records, however, are inherited. There is a
permanent, dynamic link from a child back to its parent.

8.3.1

Scenario Selection

You can change the current scenario by simply using the Scenario drop-down list located on the Analysis
Toolbar on the main application window. When you select a different scenario, your current input data,
calculation options, and calculated results (if available) will reflect the selected scenario and the
alternatives it references.

8.3.2

Editing Scenarios
Once scenarios and alternatives are created, you do not need to take any special steps to input data into the
alternatives referenced by the current scenario. This happens automatically as you make changes to your
data. Changes to your data are always applied to the alternatives in your active scenario. For example,
consider that a pipe has a 12" diameter in the alternative storing data for the Base scenario. Then you
switch to Scenario 2, which references another alternative, and change the pipe diameter to 16". The new
value will automatically be associated with the alternative in Scenario 2. If you switch back to the Base
scenario, the pipe diameter will revert to 12".
You can also enter data directly into an alternative using the Alternatives Editor. This editor allows you
to see all of the changes that you have made in a single alternative. If you make an unintended change to
the active child scenario and you wish to remove it, go to the tabular editor for the type of input data you
changed, and uncheck the leading check box on the record(s) for the elements you wish to restore.
Scenarios currently only track modifications to the input data associated with existing network elements.
They do not allow you to track modifications to the network topology itself (e.g. additions and deletions of
network elements).

8.3.3

Scenario Manager
The Scenario Manager allows you to create, edit, and manage scenarios. There is one built-in default
scenario - the Base scenario. If you wish, you only have to use this one scenario. However, you can save
yourself time by creating additional scenarios that reference the alternatives needed to perform and recall
the results of each of your calculations. There is no limit to the number of scenarios that you can create.
The Scenario Manager is divided into four sections:
1.

The three buttons that run across the top of the window:

− Tutorial - Open the tutorials.
− Close - Close the Scenario Manager.
− Help - Open the on-line help.
2.

The series of five buttons running along the left side of the window:

Chapter 8 - Scenarios and Alternatives

141

− Scenario Wizard - Open the Scenario Wizard, which walks you step-by-step through the
creation of a new scenario.
− Scenario Management - Offers a menu of options for creating, editing, and managing scenarios:
Add - Prompts for a name, then creates a new child or base scenario. If you create a child scenario,
it will be based on the scenario that is currently highlighted.
Edit - Open the Scenario Editor for the scenario that is currently highlighted.
Rename - Rename an existing scenario. This invokes an in-place editor in the tree view of the
available scenarios. Make the desired changes to the existing name and press Enter.
Delete - Delete the scenario that is currently highlighted.
Report - Generate a summary report for the scenario that is highlighted, including alternatives,
calculation options, notes, and results.
− Alternatives - Open the Alternatives Manager for creating, editing, and managing alternatives.
− Batch Run - Open the Batch Run dialog for selecting from among the available scenarios and
initiating calculations.
− Scenario Comparison - Open the Annotation Comparison Wizard, which allows you to create
a drawing displaying the differences in input and output variables between two scenarios.
3.

The pane in the center of the dialog:

− Scenarios Pane - Available scenarios in a hierarchical tree showing the parent-child relationships.
You can right-click any scenario to perform scenario management functions on it. You can
double-click parent scenarios to expand or collapse the child scenarios beneath them.
4.

The pane on the right side of the dialog, which displays a variety of information depending on
which of the following tabs is selected:

− Alternatives tab - Alternatives referenced by the highlighted scenario, showing the type and name
for each alternative. An icon distinguishes whether the alternative belongs to the scenario
or is
inherited from its parent scenario . Double-click any alternative to open the Alternatives
Editor.
− Summary tab - Summary of the calculation options for the highlighted scenario, and any notes
you have associated with it.
− Results tab - Summary of the last calculation performed for the highlighted scenario.
When you delete a scenario, you are not losing data records because scenarios never actually
hold calculation data records (alternatives do). The alternatives and data records referenced by
that scenario will still exist until you explicitly delete them. By accessing the Alternative
Manager, you can delete the referenced alternatives and data records.

To open the Scenario Manager window, select Analysis / Scenarios. Or, click the
scenario drop-down list in the main application window.

button next to the

Batch Run
Performing a batch run allows you to set up and run calculations for multiple scenarios at once. This is
helpful if you want to queue a large number of calculations, or simply manage a group of smaller
calculations as a set. The list of selected scenarios for the batch run will remain with your project until you
change it.

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Using the dialog is simple. First, check the scenarios you want to run and click the Batch button. Each
scenario will be calculated. You can cancel the batch run between any scenario calculation.
When the batch is completed, the scenario that was current will remain current, even if it was not one that
was calculated. Select a calculated scenario from the main window drop-down list to see the results
throughout the program, or select it from the Scenario Manager and click the Results tab to preview the
results.
The Batch Run dialog contains a Select button that displays options you can use to select all scenarios or
clear your selections.

Creating Scenarios to Model "What If?" Situations
The scenario management feature was designed to let you model "What If?" situations by easily switching
between different input data sets without having to re-enter data. Comparing different output results is just
as simple.
To create a new scenario:

8.3.4

1.

Open the Scenario Manager dialog by clicking the Scenario Manager button
down scenario list in the main application window.

2.

Click the Scenario Wizard button in the upper left of the Scenario Manager dialog.

3.

Complete each step in the Scenario Wizard - Name the new scenario, choose which scenario to base it
on, and choose the alternatives to be included. Click Next between each step, and click Finish when
you are done.

4.

Close the Scenario Manager dialog. Notice the scenario you have just created is displayed as the
current scenario in the Scenario choice list in the main application window.

5.

Proceed to modify your model with the changes you want recorded in the new scenario.

next to the drop-

Scenario Wizard
The Scenario Wizard will guide you step-by-step through the process of creating a new scenario.
These are the basic steps for creating a new scenario:


Name - Name the scenario and add some comments if you wish.



Base - Select a scenario on which to base the new scenario.



Calculation - Choose the type of calculation that you would like to perform, as well as other
calculation options.



Alternatives - Specify the alternative types with which you would like to work.



New/Existing - Create and/or select alternatives for your new scenario.

• Preview - Preview the scenario, and create it when satisfied.
To access the Scenario Wizard, open the Scenario Manager and click the Scenario Wizard button.

Scenario Wizard - Step 1
Here you can enter a unique name and an optional note for the new scenario that you are creating.
The Name field allows you to input a distinguishing name for this scenario. A default name is provided,
but we recommend that you change it to something more descriptive. If the new scenario will be based on
another scenario, you may want a name that indicates what will be different about the new scenario. For
example: "Post Development".

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The next field is optional, and allows you to input free-form text that will be associated with the new
scenario. Use it to make detailed notes about the conditions the scenario will model.
Click the Next button to proceed to the next step in defining a new scenario.

Scenario Wizard - Step 2
Click the existing scenario on which you would like to base your new scenario. Your new child scenario
will inherit data from this parent scenario, and will be initialized with the same calculation settings and
options. The Scenario Wizard, designed to introduce the user to scenarios, does not allow you to create
new base scenarios.
Existing scenarios in your project are displayed in a "tree" structure, giving you a graphic depiction of the
parent-child relationships.
Click the Next button to proceed to the next step.

Scenario Wizard - Step 3
This tab of the Scenario Wizard allows you to specify the type of calculation to be associated with the
scenario you are creating, either Extended Period or Steady State.
You can choose to perform a Design for a Steady State run, and also specify the Extreme Flow Setup and
the Pattern Setup.

Scenario Wizard - Step 4
Check the boxes next to the types of alternatives you want to include in the new scenario. The alternatives
for boxes you do not check will be inherited from the specified parent scenario. You will be free to add or
remove alternatives to the scenario after you create it.
Click the Next button to proceed to the next step in defining a new scenario.

Scenario Wizard - Step 5
Here you are asked to specify the source for each alternative you have requested in the previous tab.


Create New Alternative - If you choose to create a new alternative, it will inherit from the same type
of alternative in the specified or parent scenario. This means it will initially use all the same input data
values. Enter a unique and descriptive name for the new alternative.



Use Existing Alternative - If you choose to use an existing alternative, you will be shown the tree of
existing alternatives from which to choose. In this case, you will not be creating a new alternative for
use in the scenario, and instead may actually be sharing an alternative with another scenario.
Click the Next button to proceed to the next step.

Scenario Wizard - Step 6
The last step of the Scenario Wizard displays a summary of the scenario you have defined and are about to
create.
In the left pane is a preview of the scenario as it relates to its parent and other scenarios. In the right pane is
a list of the alternatives it references, showing their labels and types. An icon indicates whether a given
alternative is local to the new child scenario, or if it is inherited from the specified or parent scenario.
If you are satisfied, click the Finished button to create the new scenario.

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Scenario Editor
The Scenario Editor is the control center for each analysis. It is the place where you access or change all
the information for performing a single calculation (alternatives, calculation type, calculation options,
results, and notes). It is organized by the following tabs:


Alternatives - Edit or view the alternatives to be used by this scenario.



Calculation - Specify the type of hydraulic/water quality calculations to be performed, and click the
GO button.



Results - View the hydraulic/water quality calculation results summary.

• Notes - Edit or view notes for this scenario.
To open the Scenario Editor for the active scenario, click the GO button on the toolbar. To open the
Scenario Editor for any scenario, select Analysis\Scenarios from the pull-down menu to open the
Scenario Manager, right-click the scenario that you wish to edit, and select Edit from the pop-up menu.
Or, highlight the scenario you wish to edit, click the Scenario Management button, and select Edit.

Alternatives Tab
The Alternatives tab, located in the Scenario Editor, allows you to specify the alternatives that will be
used by this scenario. There is one row for each Alternative Type. You need only concern yourself with
the rows that correspond to the changes you would like to model using this scenario.
To specify the alternatives you would like to work with, simply click the check box next to the alternative
type. For example, if you would like to see how your system behaves by changing the shape or size of a
few pipes, then click the check box next to the Physical Properties Alternative row.
If you would like to use an existing alternative that you have already set up, use the drop-down list to
choose the desired alternative. If you would like to create a new alternative, click the New button. You
will be asked to name the new alternative, and the Alternatives Editor will open.
The Scenario Wizard will walk you through all of the steps required to create a new scenario. If you are
unsure how to specify the alternatives that you would like to work with, we recommend that you use this
wizard.
When this scenario is active, the alternatives that you specify here will be active. Changes that
you make to your model will be made in these alternatives. When you calculate this scenario,
these are the alternatives that will be used.
This tab will take on a different appearance depending on whether you are editing a base
scenario or child scenario. When editing a base scenario, the checkbox column described above
will not be present. You can use the ellipsis (…) button located to the right of each drop-down
list to access the associated Alternatives Manager.

Calculation Tab
The Calculation tab, located on the Scenario Editor, lets you define the type of calculation and analysis
you wish to perform for this scenario, as well as setting various calculation options.
To calculate the model you must perform the following steps:
1.

Choose from either Steady State or Extended Period.

2.

If performing a Steady State analysis select the following parameters:

− Check Design if you wish SewerCAD to perform an Automated Design on the gravity portion of
the network.

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145

− Select an Extreme Flow Setup from the Extreme Flow Setup Manager.
3.

If performing an Extended Period analysis select and enter the following parameters:

− Duration - Specify the duration of the Extended Period Simulation.
− Hydraulic Time Step - Specify the time increment between hydraulic backwater analyses in the
gravity portions of the network.
− Hydrologic Time Step - Specify the routing increment used to generate hydrographs in the
gravity system, and the time increment used in the pressure portions of the network.
− Select a Pattern Setup from the Pattern Setup Manager.
4. Click the GO button.
The Physical Properties and Design Constraints alternatives used for the design will be displayed.
In Stand-Alone mode, if the model has not been calculated, or if the input data has been changed
since the last calculation, the word COMPUTE (highlighted in Red) will appear in the status
pane in the lower right corner of the main application window. This is a signal that the model
needs to be recalculated.

Results Tab
The Results tab contains a summary of the last calculation performed using this scenario. Click the Save
button to save the results to an ASCII text file. Click the Print Preview button to preview the Scenario
Results Summary Report.
To open the Results tab for the active scenario: Click the GO button on the toolbar, or select Analysis \
Compute from the pull-down menu. In the resulting dialog, click the Results tab.
To open the Results tab for a specific scenario: From the Scenario Manager, right-click the scenario that
you wish to edit, and select Edit from the pull down menu that appears. In the resulting dialog, click the
Results tab.
Immediately after you run the calculations, the Results tab displays automatically. You will
notice a green, yellow, or red light in that tab indicating how successful the computations were.
The light and folder color provides you with the following information:
Green light - Calculations were run successfully, without any warning or error messages being generated.
Yellow light - Calculations were run successfully, without error messages being generated. However, there
are one or more warning messages. Warnings are displayed in the results summary in this tab.
Red light - Calculations were not run successfully and error messages were generated, as shown in the
results summary of this tab.
In order to generate a Scenario Summary Report, click the Report button. Click the Element Messages
button to open up a table that displays all the messages generated during the run.
Double click the folders or click the + sign to open them up and display messages relevant to the folder’s
caption. When you click the copy button or save button the exposed text will be stored.

Notes Tab
The memo field on the Notes tab allows you to input paragraph text that will be associated with the new
scenario. Use it to make detailed notes about the conditions that the scenario will model.

Notes

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Modeling and Design Capabilities
9.1 Calculate
To run network calculations, you must set parameters in the following sections on the Calculation tab of
the Scenario Editor:


Calculation Type - Perform either a Steady State or Extended Period analysis.



Steady State - Choose whether or not to run a design and select an Extreme Flow Setup from the
Extreme Flow Setup Manager. Clicking the ellipsis (…) button in the Extreme Flow Setup field
will open the Extreme Flow Setup Manager.



Extended Period - Enter a Duration, Hydraulic Time Step, and a Hydrologic Time Step. Also, select
a Pattern Setup from the Pattern Setup Manager. Clicking the ellipsis (…) button in the Pattern
Setup field will open the Pattern Setup Manager.
Click the Options button to check or change calculation settings. After exiting the Calculation Options
dialog, click the

button to start the calculations.

The Check Data button performs a quick check of your input data and displays any errors
found. This function is automatically performed when you run a calculation.

9.1.1

Calculation Type Section
This section lets you specify whether you are in Steady State or Extended Period mode.

9.1.2



Steady State - Runs the model for a single instant in time with extreme flow factors applied.



Extended Period - Runs the analysis over a specified duration of time with loading patterns applied.

Steady State Section
This section allows you specify whether you would like to perform an automated design and lets you select
an Extreme Flow Setup.
If Design is checked, all pipe invert elevations, diameters, and structures that are selected for design will
have the corresponding values updated automatically.
The values that may change due to the design process are stored in the Physical Alternative,
using the Design Constraints specified in the Design Constraints alternative. When you are
ready to do the calculation, you will be asked if you want to save this new data in a separate
Physical Alternative, in case you want to preserve your current Physical data.

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In the Extreme Flow Setup field you can specify which previously created Extreme Flow Setup to
associate with the Steady State run. Clicking the ellipses (…) button will open the Extreme Flow Setup
Manager.

9.1.3

Extended Period Section
This section lets you specify the following parameters necessary to run the Extended Period Simulation.


Duration - Length of simulation.



Hydraulic Time Step - Time increment between gravity backwater analyses.



Hydrologic Time Step - Time increment between computed hydrograph ordinates. This also serves as
the increment used in the pressure calculations.



Pattern Setup - In this field you can specify which previously created Pattern Setup to associate with
the Extended Period run. Clicking the ellipses (…) button will open the Pattern Setup Manager.

9.2 Calculations Options
Calculations depend upon a variety of parameters that may be configured by you.
This program provides defaults for each of the calculation options. If you make changes to the calculation
options and decide that you would like to return to the default settings, use the Reset button on the
Calculation Options dialog.
The dialog is divided into seven tabs:


Gravity Hydraulics



HEC-22



AASHTO



Generic Structure Loss



Convex Routing



Steady State Loading

• Pressure Hydraulics
To access the Calculation Options dialog, click the Options button in the Scenario Editor , or select the
button and click the Options... button.

9.2.1

Gravity Hydraulics Tab
The Gravity Hydraulics tab is the place where you can adjust the hydraulic options relating to the gravity
portion of the calculation. The following sections are available on the Gravity Hydraulics tab:


Flow Profile Method



Hydraulic Grade Convergence Test



Average Velocity Method



Minimum Structure Headloss

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149

Flow Profile Method Section
This section lets you specify whether you are performing a Backwater Analysis or a Capacity Analysis for
the gravity portions of the network.
If you select the backwater analysis, you need to specify the Number of Flow Profile Steps. The
gradually varied flow profile within each pipe divides the pipe into internal segments prior to calculation of
the hydraulic grade. The default value is five, and it is recommended that the value entered here be at least
five segments for accuracy. Increasing this number will increase the accuracy of the hydraulic grade
calculation, but will also make the network take longer to calculate.
The higher the number of steps, the more accurate the results, but the slower the calculations. A
value of five steps should be accurate enough in most cases.

Hydraulic Grade Convergence Test Section
This section contains the tolerance value constraining the Hydraulic Grade Convergence Test. In a full
network calculation, this value is taken as the maximum absolute change between two successive solutions
of the hydraulic grade at any junction or manhole in the system. This test is used to optimize the
performance of the system solutions. It minimizes the number and extent of hydraulic grade line
computations in the upstream direction. For a given discharge, the upstream propagation of headlosses
through pipes will continue until two successive calculations change by an absolute difference of less than
this test value.
HGL Convergence Test value is also used in the standard step gradually varied flow profiling algorithm. If
two successive depth iterations are within this absolute test value, the step is solved.

Average Velocity Method Section
This section allows you to choose the method used to calculate the velocity and the travel time through the
pipe. You have the following four options:


Actual Uniform Flow Velocity



Full Flow Velocity



Simple Average Velocity



Weighted Average Velocity
You can find more information on the different velocity methods in Appendix B of the help.

Minimum Structure Headloss
This section allows you to specify a minimum structure headloss. If the system calculates a structure
headloss that is lower then this value, the value specified in the Minimum Headloss field will be used.
This option applies to all structure headloss methods except for the Absolute Method. Absolute headlosses
will not be overridden, even if they are less then the value specified in this option.

9.2.2

HEC-22 Tab
This tab is where you enter the values governing the calculations of the HEC-22 Energy Loss Method. The
specifics of this tab are presented below:


HEC-22 Energy Loss Method - Enter the Elevations Considered Equal Within value, which is the
maximum elevation distance that pipes entering a node can be separated by and still be considered to
be at the same elevation.

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Chapter 9 - Modeling and Design Capabilities
Correction for Benching - Contains values for the items in the following list governing the correction
for benching sections:


Flat Submerged



Flat Unsubmerged



Depressed Submerged



Depressed Unsubmerged



Half Bench Submerged



Half Bench Unsubmerged



Full Bench Submerged



Full Bench Unsubmerged

You can find more information on the HEC-22 Energy Loss Method in Appendix B of the help.

9.2.3

AASHTO Tab
This tab is where you can enter the values governing the calculations of the AASHTO Headloss Method.
The following sections are available:


Bend Angle and Loss section



Other Factors section
You can find more information on the AASHTO Headloss Method in Appendix B of the help.

AASHTO Bend Angle and Loss Section
This section allows you to enter the bend angles and associated bend loss coefficients, Kb, that are used in
the calculation of headloss in the AASHTO Headloss Method.

AASHTO Other Factors Section
In this section, you can enter the values for the other factors that govern the calculation of headlosses using
the AASHTO Headloss Method. These factors are presented in the following list:

9.2.4



Expansion



Contraction



Shaping Adjustment



Non-Piped Flow Adjustment

Generic Structure Loss Tab
Calculation Options Generic Structure Loss Tab
On this tab, you can change the methodology for selecting the upstream pipe when computing the headloss
for a structure using the Generic Headloss Method. The three methodologies are described below.

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Pipe With Maximum QV - If this item is selected, the program will use the non-plunging upstream
pipe with the largest flow times velocity to calculate the upstream velocity head used in the generic
headloss equation.



Pipe With Minimum Bend Angle - If this item is selected, the program will use the upstream pipe
with the smallest bend angle to calculate the upstream velocity head used in the generic headloss
equation. The methodology should be used when you want to assume that the upstream pipe most
closely aligned with the downstream pipe is the one that is the most hydraulically significant.



Pipe With Maximum Velocity Head - If this item is selected, the program will use the non-plunging
upstream pipe with the largest velocity head to calculate the upstream velocity head used in the generic
headloss equation. Note that if this method is used, pipes with very small flows may be selected as the
governing pipe, even though they are not hydraulically significant.
The methodology that is selected here will be used for all structures that employ the generic headloss
method.

9.2.5

Convex Routing Tab
In this section you can adjust the Peak Flow Ratio for use when selecting a representative flow rate from
the hydrograph to be routed when calculating the C parameter used to perform the routing calculations.
You can find more information on the routing methods used in SewerCAD in Appendix B of the
help.

9.2.6

Steady State Loading Options Tab
In this section the user specifies how SewerCAD should handle hydrographs during a steady state analysis.
One of the following methods can be selected:

9.2.7



Peak - The peak of the hydrograph will be used as the load.



Average - The average of all the flows in the hydrograph will be used as the load.



Minimum - The lowest flow of the hydrograph will be used as the load.



Zero - The hydrographs will be ignored during the analysis.

Pressure Hydraulics Tab
The Pressure Hydraulics tab is the place where you can adjust the hydraulic options relating to the
pressure portion of the calculation. For more information on any of the options on this tab, see the
following sections:


Pressure Options



Gravity Pressure Interface Options

Pressure Options Section
Specify the hydraulic settings controlling Pressure Flow computations, as follows:


Trials - A unitless number that defines the maximum number of iterations to be performed for each
hydraulic solution. The default value is 40.



Accuracy - A unitless number that defines the convergence criteria for the iterative solution of the
network hydraulic equations. When the sum of the absolute flow changes between successive
iterations in all links is divided by the sum of the absolute flows in all links, and the result is less than
the Accuracy, the solution is said to have converged. The default value is 0.001, and the minimum
allowed value for Accuracy is 1.0 x 10-5.

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Chapter 9 - Modeling and Design Capabilities
Use Controls in Steady State Analysis - When this toggle is on, the pressure subnetwork will be
evaluated after each trial to determine if any controls are triggered by changes to the system
hydraulics. This option enables pumps to change status or setting, and enables pipes to open or close.
If this option is not selected, controls will be ignored. Pump and pipe status will be based on initial
status and settings only.

In most cases, the default values are adequate for the hydraulic analysis. Under special
circumstances, the accuracy may need to be adjusted downwards. This is necessary when the
model converges yet there are larger than acceptable discrepancies between the total inflow and
total outflow at individual nodes.

Gravity Pressure Interface Options Section
In this section, you can specify the parameters affecting the transition from a gravity network to a pressure
system during a Steady State analysis, as follows:


Wet Well Increment - Unless a wet well is set to a Fixed Level, this is the increment that is used to
attempt to balance the wet well level such that the total flow out is equal to or greater than the total
flow in. See the Hydraulic Transition from Gravity to Pressure Network in Appendix B for a further
explanation.



Use Pumped Loads - Loads discharging from a pressure subnetwork into a gravity subnetwork can be
treated as fixed flow loads by selecting the option Use Pumped Flows. If this option is not selected,
the discharging load will be recreated as a combination of dry, wet, and known loads (in accordance
with the loads entering the pressure subnetwork).

9.3 Pattern Manager
9.3.1

Patterns
The extended period analysis is actually a series of Steady State analyses run against time-variable loads
such as sewer inflows, demands, or chemical constituents. Patterns allow you to apply automatic timevariable changes within the system. The most common application of patterns is for residential or industrial
loads. Diurnal curves are patterns that relate to the changes in loads over the course of the day, reflecting
times when people are using more or less water than average. Most patterns are based on a multiplication
factor versus time relationship, whereby a multiplication factor of one represents the base value (which is
often the average value).
Using a representative diurnal curve for a residence as illustrated below, we see that there is a peak in the
diurnal curve in the morning as people take showers and prepare breakfast, another slight peak around
noon, and a third peak in the evening as people arrive home from work and prepare dinner. Throughout the
night, the pattern reflects the relative inactivity of the system, with very low flows compared to the average.

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153

Typical Diurnal Curve

This curve is conceptual and should not be construed as representative of any particular
network.
There are two basic forms for representing a pattern: stepwise and continuous. A stepwise pattern is one
that assumes a constant level of usage over a period of time, and then jumps instantaneously to another
level where it remains steady until the next jump. A continuous pattern is one for which several points in
the pattern are known and sections in between are transitional, resulting in a smoother pattern. For the
continuous pattern in the figure above, the multiplication factor and slope at the start time and end times are
the same. This is a continuity that is recommended for patterns that repeat.
Because of the finite time steps used for calculations, this software converts continuous patterns into
stepwise patterns for use by the algorithms. In other words for a time step a multiplier is interpolated from
the pattern curve. That multiplier is then used for the duration of the time step, until a new multiplier is
selected for the next time step.
Patterns provide a convenient way to define the time variable aspects of system loads.

9.3.2

Pattern Manager
Patterns provide an effective means of applying time-variable system loads to the distribution model. The
Pattern Manager allows you to do the following:


Add - Click the Add button. This action opens the Pattern Editor where the specifics of the pattern
can be entered.



Edit - Select the label of the pattern you wish to edit, and click the Edit button. The Fixed pattern
cannot be edited.



Duplicate - Select the label of the pattern you wish to duplicate, and press the Duplicate button. The
Fixed pattern cannot be duplicated.



Delete - Select the label of the pattern you wish to delete, and click the Delete button. The Fixed
pattern cannot be deleted.
In this program, an individual loading node can support multiple hydraulic loads. Furthermore,
each load can be assigned any hydraulic pattern. This powerful functionality makes it possible to
model any type of extended period simulation.

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To access the Pattern Manager select Analysis / Patterns from the pull-down menus, or click the ellipsis
(…) button next to any pattern choice list.

9.3.3

Pattern Editor
A pattern is a series of time step values, each having an associated multiplier value. During an extended
period analysis each time step of the simulation uses the multiplier from the pattern corresponding to that
time. If the duration of the simulation is longer than the pattern, the pattern is repeated. The selected
multiplier is applied to any baseline load that is associated with the pattern.
Defining Patterns


Label - A required name to uniquely identify the pattern. This name appears in the choice list when
applying patterns to hydraulic demands or constituent source loads.



Start Time - A value between 0 and 24 that specifies the first time step point in the pattern. All other
pattern time step points are referenced from this start time. This program automatically adjusts your
pattern when you start an Extended Period Analysis at a time other than zero.



Starting Multiplier - The multiplier value of the first time step point in your pattern. Any real
number can be used for this multiplier (it does not have to be 1.0).
Time Step Points


Time From Start - The amount of time from the Start Time of the pattern to the time step point being
defined.

• Multiplier - The multiplier value associated with the time step point.
Format


Stepwise - The multiplier values are considered to be the average value for the interval between the
specified time and the next time. Patterns using this format will have a "staircase" appearance.
Multipliers are set at the specified time and held constant until the next point in the pattern.



Continuous - The multipliers are considered to be the instantaneous values at a particular time.
Patterns using this format will have a "curvilinear" appearance. Multipliers are set at the specified time,
and are linearly increased or decreased to the next point in the pattern.
Patterns must begin and end with the same multiplier value. This is because patterns will be
repeated if the duration of the Extended Period Analysis is longer than the pattern duration. In
other words, the last point in the pattern is really the start point of the pattern's next cycle.
An Extended Period Analysis is actually a series of Steady State analyses for which the boundary
conditions of the current time step are calculated from the conditions at the previous time step.
This software will automatically convert a continuous pattern format to a stepwise format so that
the demands and source concentrations remain constant during a time step.
An individual loading node can support multiple hydraulic loads. Furthermore, each load can be
assigned any hydraulic demand pattern. This powerful functionality makes it easy to combine
two or more types of demand patterns (such as residential and institutional) at a single loading
node.
Use the Report button to view or print a graph or detailed report of your pattern.

To access the Pattern Editor, click the Add or Edit button on the Pattern Manager.

Chapter 9 - Modeling and Design Capabilities

9.3.4

155

Pattern Graph and Report
You can generate a graph or a full report of a pattern that represents the multiplier variable of the pattern
over time. To do so, open the appropriate Pattern Manager dialog and access the pattern for which you
would like to generate output. From the Pattern Editor dialog, click the Report button, and select Graph
or Detailed Report.

9.4 Pattern Setup Manager
The Pattern Setup Manager lets you define a list of Pattern Setups. A Pattern Setup allows you to match
unit sanitary (dry weather) loads with appropriate loading patterns. A Pattern Setup is associated with each
scenario as specified in the Calculation tab of the Calculate dialog. Each scenario can use a different
Pattern Setup, thus allowing you to model different loading alternatives for different extended period
simulations.


Add - Click the Add button. This will open the Pattern Setup dialog where the specifics of the pattern
can be edited.



Edit - Select the label of the pattern setup you wish to edit, and click the Edit button.



Duplicate - Select the label of the pattern setup you wish to duplicate and click the Duplicate button.

• Delete - Select the label of the pattern setup you wish to delete, and click the Delete button.
The Pattern Setup Manager can be accessed by selecting Analysis / Pattern Setups from the pull-down
menus, or from the Calculation tab of the Calculate dialog.

9.4.1

Pattern Setup Editor
The Pattern Setup can be named by editing the Label field.
The Pattern Setup Editor contains two tabs:


Used Loads - Contains the unit sanitary (dry weather) loads that are currently being used in the
project.



Unused Loads - Contains the loads not currently associated with any node accepting loads (manholes,
wet wells and pressure junctions) in the current project. This dialog also lets you select the loading
pattern associated with each currently unused load.
If you have not yet associated any loads with manholes, wet wells, or pressure junctions, the Used
Loads tab list will be empty. In that case, you can either select the loading patterns in the Unused
Loads tab, or associate loads to specific nodes first. Then come back to the Used Loads tab to
select the diurnal patterns associated with the currently used loads.

The following columns are contained in the table on each of the tabs:


Unit Load - The name of the unit sanitary load to be associated with a Pattern Setup.



Diurnal Pattern - A list of the currently defined patterns in the Pattern Managers. You can access
the Pattern Manager by clicking the ellipsis (…) button.
If no diurnal patterns are selected, the program will assume that the loads are fixed over the
entire time period.

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9.5 Extreme Flow Setup Manager
The Extreme Flow Setup Manager lets you define a list of Extreme Flow Setups. An Extreme Flow
Setup allows you to match unit sanitary loads with appropriate extreme flow factor methods. The Extreme
Flow Setup is associated with each scenario as specified in the Calculation tab of the Calculate dialog.
Each scenario can use a different Extreme Flow Setup, thus allowing you to model different load
alternatives (average, minimum daily, maximum daily, etc).


Add - Click the Add button. This will open the Extreme Flow Setup dialog where the specifics of the
control can be edited.



Edit - Select the description of the Extreme Flow Setup you wish to edit, and click the Edit button.



Duplicate - Select the description of the Extreme Flow Setup you wish to duplicate and click the
Duplicate button.



Delete - Select the description of the Extreme Flow Setup you wish to delete, and click the Delete
button.
The Extreme Flow Setup Manager can be accessed by selecting Analysis / Extreme Flows from the pulldown menu, or from the Calculation tab of the Calculate dialog.

9.5.1

Extreme Flow Setup Editor
The Extreme Flow Setup Editor contains two tabs as follows:


Used Loads - Contains the unit sanitary loads that are currently being used in the project.



Unused Loads - Contains the loads not associated with any node accepting loads (manholes, wet wells
and pressure junctions) in the current project. This dialog also lets you select the extreme flow factor
method associated with each currently used and unused load.
If you have not yet associated any loads with manholes, wet wells, or pressure junctions, the Used
Loads tab list will be empty. In that case, you can either select the extreme flow methods in the
Unused Loads tab, or associate loads to specific nodes first. Then come back to the Used Loads
tab to select the extreme flow methods associated with the currently used load.

The following columns are contained in the tables on both tabs:


Unit Load - The sanitary load to be associated with an Extreme Flow Method.



Loading Unit Type - Reports the type of loading corresponding to each unit load, as defined in the
Unit Sanitary (Dry Weather) Load Library.



Extreme Flow Method - Lists the currently defined methods in the Extreme Flow Factor Method
Library. You can edit this library by clicking the ellipsis (…) button.



Constant - Available only for the Constant Extreme Flow Method, it simply multiplies the unit load
by that constant.



Adjustment Multiplier - Used to adjust an existing Extreme Flow Method. The following formula
is used:
EFF = (EFF - 1)/AM + 1

Where EFF is the Extreme Flow Factor used to transform the base (average) load to an extreme load.
The Adjustment Multiplier does not change the Extreme Flow Method, but changes the extreme flow
factor for the selected unit sanitary load. None and Constant Extreme Flow Methods cannot be adjusted.

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157

If no extreme flow factor method is selected, the program will assume that the loads are not
transformed. In this case, a warning will be issued when you attempt to calculate the system.

9.6 Default Design Constraints
Pipes diameters, invert elevations, and gravity structures can all be designed with the same set of design
constraints. You also have the option to adjust these values individually for each pipe or structure.
The Default Design Constraints dialog box is divided into two tabs:

9.6.1



Gravity Pipe



Gravity Structure

Gravity Pipe Tab
The Gravity Pipe tab allows you to enter default constraints to be used for the design of pipes when
performing a calculation run in design mode. The following sections are available:

9.6.2



Default Constraints



Extended Design

Default Constraints Section
In this section, you can specify the following default constraints to be used for the design of gravity pipes:


Minimum and Maximum Velocity



Minimum and Maximum Cover


Minimum and Maximum Slope.
The Default Design Constraints dialog can be accessed by selecting Analysis / Default Design
Constraints from the pull-down menu.

9.6.3

Extended Design Section
This section lets you specify if the following design parameters are to be used. If they are to be used, you
can also specify the associated default value:


Part Full Design - Allows you to specify the Design Percent Full target to be used by the design
algorithm.



Allow Multiple Sections - Allows the design algorithm to use more than one identical section in
parallel, up to the specified Maximum Number Sections.



Limit Section Size - Limits the pipe section height to a Maximum Design Section Rise value during
the design process.

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Chapter 9 - Modeling and Design Capabilities

Gravity Structure Tab
This tab lets you specify the default design constraints for all gravity structures when performing
calculations in design mode. During an automatic design, the program will adjust the elevations of the
pipes adjacent to the structure according to the structure’s matching constraints. The two choices for
matching are Inverts and Crowns. Additionally, the downstream pipe can be offset from the upstream
pipe(s) by a specified amount. This value is called the Matchline Offset. Optionally, the program supports
the design of drop structures. In some situations, drop structures can minimize pipe cover depths while
maintaining adequate hydraulic performance.

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Chapter 10
Cost Estimating
10.1 Overview
The Cost Manager allows you to calculate a planning level estimate of the capital costs associated with an
entire system or any portion of a system. This makes it easy to compare the costs associated with various
scenarios, thus helping to ensure that the most cost-effective design is chosen.
The costs associated with a particular element are broken down into two categories: construction costs and
non-construction costs. The total cost for each element is simply the sum of the total construction and nonconstruction costs. The total cost for a scenario is computed by summing the total cost for every element
selected to be included in the cost analysis, and then applying any global cost adjustments that you have
defined.
Each construction cost item is expressed as a combination of a quantity, unit, and unit cost. The total cost
associated with a single construction cost item is the quantity multiplied by the unit cost. The unit cost for
each construction cost item can either be entered directly by you, or if the element is a pipe or gravity
structure (e.g. inlet, manhole, junction, junction chamber) it can be calculated based on a Unit Cost
Function. A Unit Cost Function is a way to relate a property of the element, such as the diameter of a pipe,
to the unit cost. This makes it easy to assign a Unit Cost Function to an element. The cost of the element is
then automatically updated when you modify the physical characteristics of the system.
The other type of cost is non-construction. Non-construction cost items are specified as either a lump sum
or as a percentage of the total construction costs. This type of cost can be useful when trying to explicitly
account for itmes like omissions and contingencies.
In addition to specifying the costs for each element in the system, you can also make adjustments on a
system level to the total cost of all the elements included in the cost analysis. This makes it easy to account
automatically for contingencies and adjustments on a scenario level.
You do not need to have a hydraulically valid network to perform a cost analysis. You can
quickly calculate the cost associated with a system at any time through the Cost Manager.

10.2 Cost Manager
The Cost Manager allows you to quickly compute and compare the costs associated with your different
scenarios. This dialog provides you with a convenient place to view, edit, and calculate project level cost
data. This dialog is divided into three sections that are described below:


Button Section - This column of buttons provides access to the key pieces of data involved
in a cost analysis.



Center Pane - This pane displays an explorer view of the cost information for various
scenarios.

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Left Pane - This pane displays the contents of the item selected in the center pane.

To open the Cost Manager, select Analysis / Compute Costs from the pull-down menu, or click the
button on the Analysis toolbar.

10.2.1

Cost Manager - Button Section
On the right side of the Cost Manager is a column of buttons that provide access to the key pieces of data
involved in a cost analysis. Each of these buttons is described as follows:


Unit Cost Functions - Opens the Unit Cost Function Manager, which is the place to add new or edit
existing functions describing the relationship between a model attribute and the unit price for the
element. For pipes, this might be a table of data relating the pipe material to the cost per unit length.



Cost Alternatives - Opens the Capital Cost Alternatives Manager where you can quickly create
different cost alternatives. For example, you may wish to compare the cost associated with different
cost functions, or to separately calculate the cost of different phases of construction.



Cost Adjustments - Opens the System Cost Adjustments Table for the selected scenario. This is the
location where you enter adjustments that you wish to make on a scenario level.



Active Scenarios - Opens the Active Cost Scenarios dialog where you can select which scenarios will
appear in the Cost Manager.



Cost Reports - Opens a menu that provides access to one of the predefined cost reports detailing the
costs associated with a particular scenario. The reports that can be opened through this button include:
detailed report , element summary report, project summary report, pipe costs report, and warnings
report.

To open the Cost Manager, select Analysis / Compute Costs from the pull-down menu, or click the
button on the Analysis toolbar.

10.2.2

Cost Manager - Center Pane
When you open the Cost Manager, this pane will contain an explorer view of all the scenarios in the file.
The total cost of each scenario is displayed to the right of the scenario label. If cost data was specified for a
scenario, you will see a small ‘+’ symbol to the left of the folder icon. You can click this symbol to get an
expanded view of the costs associated with a scenario.
In the first level of the expanded view you will see the subtotal for each type of element included in the cost
analysis, as well as the total cost adjustments made to the scenario. If you expand any of these items you
will get a view of the costs of each individual element. If you expand the view one more level you will be
able to see the construction and non-construction costs associated with an element. The contents of any
component that is selected will be displayed in the table on the pane to the left of this one.
Just above the right side of this pane is a row of three buttons, which access the following functionality:


Properties - Opens the System Cost Adjustments Table for the currently selected scenario.



Graph - Opens a pie chart of the items comprising the total cost of the scenario.



Report - Opens a tabular report on any component selected in this pane.

To open the Cost Manager, select Analysis / Compute Costs from the pull-down menus, or click the
button on the Analysis toolbar.

Chapter 10 – Cost Estimating

10.2.3

161

Cost Manager - Left Pane
This pane on the left side of the Cost Manager is used to display an expanded view of the contents of the
item selected in the center pane.
To open the Cost Manager, select Analysis / Compute Costs from the pull-down menus, or click the
button on the Analysis toolbar.

10.2.4

System Cost Adjustments Table
The System Cost Adjustments Table allows you to make adjustments to the total cost calculated for all
the elements included in the cost analysis. This may include items such as omissions and contingencies that
might be represented as a percentage of the total construction costs, or land acquisition costs that are
represented as a lump sum. Each cost adjustment consists of the following items:


Label - A unique name that identifies each cost adjustment.



Operation - The mathematical operation that should be used with the factor to compute the cost
adjustment.



Factor - A numeric value that is used with the operation and the total scenario cost to compute the cost
adjustment.
The types of operations that are supported are described below:


% of Construction - Computes the cost of the adjustment as a percentage of the total construction
costs for the scenario. For example, if the total construction cost for a scenario is $100,000 and the
numeric value in the factor field is 10, the cost adjustment is $10,000.



% of Total Cost - Computes the cost of the adjustment as a percentage of the total construction and
non-construction costs for a scenario. For example, if the total cost for all the elements in a scenario is
$200,000 and the numeric value of the factor is 15, the cost adjustment is $30,000.



Add - Adds the numeric value specified for the factor to the other costs computed for a scenario.



Lump Sum - The numeric value specified is a lump sum that is added to the other costs for the
scenario.



Multiply - Multiplies the numeric value in the factor field by the total construction and nonconstruction costs for a scenario.



Subtract - Subtracts the numeric value in the factor field from the other costs computed for the
scenario.
To open the System Cost Adjustments Table, select Analysis / Compute Costs from the pull-down

menu, or click the
Adjustments.

button on the Analysis toolbar. In the Cost Manager, click the button labeled Cost

10.3 Unit Cost Functions
10.3.1

Unit Cost Functions Manager
You can add, delete, and edit the Unit Cost Functions for your project through this manager. You will be
able to assign the cost functions defined here to one or more of the elements of the appropriate type in your
system. For example, if you define a cost function for pipes, you will be able to select this cost function
from the choice list on the Cost tab of the Pipe Element Editor.

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Use the Save command to save the Unit Cost Functions listed in the Unit Cost Functions Manager. You
can then import them into another project using the Import command. The Save and Import commands
are accessed from the File button in this dialog.

10.3.2

Tabular Unit Cost Function
This tab contains the data for Unit Cost Functions defined with tabular data. The information is defined in
the following fields:


General - Contains general information identifying the Unit Cost Function.



Attribute Value Range - Displays the range of the selected attribute in the current scenario. This
information can be useful for specifying cost data for the entire range of values in the model.

• Unit Cost Data - Specifies the tabular data relating unit cost to the value of the selected attribute.
In order to help you enter and visualize the function, use one of the following buttons at the bottom of the
dialog:


Plot - Plots the tabular data relating cost to the value of the selected attribute.



Initialize Range - Initializes the minimum and maximum values in the Attribute Value Range
section, based on all the elements present in your project for the current scenario.
If the attribute you have selected to define the Unit Cost Function is outside the defined range for
some elements in your network, the unit cost used will be the cost of the minimum or maximum
value of the attribute you defined in the table.

General Section
This section contains general information identifying the Unit Cost Function, as follows:


Label - Unique name that identifies your Unit Cost Function.



Element Type - Displays the type of element to which the function applies, which is always pressure
pipe in WaterCAD, but could also be gravity pipe, junction, inlet, manhole, or junction chamber in
SewerCAD or StormCAD.



Attribute Label - Element attribute that controls the unit cost, such as pipe diameter. This attribute is
selected when you add a new function in the Unit Cost Function Manager.

Attribute Value Range Section
This section displays the minimum and maximum values for the attribute that controls the unit cost in your
current network. Click the Initialize Range button to have these values calculated.

Unit Cost Data Table
This allows you to define the Unit Cost Function in a tabular format, preferably defining the costs
associated with the entire range of values present in your network. To display the current range of values
in your model, initialize the Attribute Value Range section by clicking the Initialize Range button.

10.3.3

Formula Unit Cost Function
The data defining formula-based Unit Cost Functions is grouped as follows:


General - General information identifying the Unit Cost Function.



Valid Cost Data Range - The range for which the function is valid for the attribute used to define the
Unit Cost Function.

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163

• Coefficients - Coefficients defining the formula relating the unit cost to the attribute value.
In order to help you enter and visualize the function, use one of the following buttons at the bottom of the
dialog:


Plot - A graph of the Unit Cost Function.



Initialize Range - The minimum and maximum values of the attribute used to define the Unit Cost
Function based on all the elements in your project.
If the function is invalid for any interval within the Valid Cost Data Range, it is set to 0.0 in that
interval. Click the Plot button to see if there are any problems with the function.
If the attribute you have selected to define the Unit Cost Function is outside the Valid Cost Data
Range for any element in the network, the formula will still be applied to calculate that element
unit cost. However, an error message for that element will be reported when computing the cost
for the system.

General Section
This section contains general information identifying the Unit Cost Function, as follows:


Label - Unique name that identifies your Unit Cost Function.



Element Type - Displays the type of element to which the function applies, which is always pressure
pipe in WaterCAD, but could also be gravity pipe, junction, inlet, manhole, or junction chamber in
SewerCAD or StormCAD.



Attribute Label - Element attribute that controls the unit cost, such as pipe diameter. This attribute is
selected when you add a new function in the Unit Cost Function Manager.



Local Unit - Unit of the attribute that controls the unit cost. This unit is used for defining the formula
coefficients.

Valid Cost Data Range Section
This section specifies the range of values for which the function is valid for the attribute used to define the
Unit Cost Function. Clicking the Initialize Range button accesses the two values based on the range of
values present in your current network.

Coefficients Section
In this section you can enter the coefficients defining the Unit Cost Function. The x-parameter, which
represents the value of the attribute on which the Unit Cost Function is based, is expressed by the unit
specified in the Local Unit field on this tab.

10.3.4

Unit Cost Function Notes
In this section you can enter optional notes related to the Unit Cost Function.

10.4 Cost Alternatives Manager
The Capital Cost Alternatives Manager allows you to edit, create, and manage your cost alternatives. It
also gives you more advanced capabilities, such as merging alternatives and creating child alternatives.

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On the right side of the dialog are a number of buttons that provide functions for managing the alternatives.
These buttons are identical to the buttons found in the Alternatives Manager. See the Alternatives
Manager topic in the Scenarios and Alternatives chapter for a description of the function of these buttons.
To access the Capital Cost Alternatives Manager, select Analysis / Alternatives from the pull-down
menu and select the Cost tab, or click the Cost Alternatives button in the Cost Manager.

10.5 Cost Reports
In addition to the standard reporting capabilities, the cost analysis feature provides a number of specialized
reports for presenting results. These reports include:


Element Detailed Cost Report - Presents a detailed view of all the cost information entered for a
single element.



Project Detailed Cost Report - Provides a detailed view of calculated cost data for every element
included in the cost analysis.



Project Element Summary Cost Report - Returns a summary of the costs for every element included
in the cost report.



Project Summary Cost Report - Provides an overview of all the costs in the system.



Pipe Costs Report - Provides an overview of the costs associated with the pipes in the project,
grouping them by material and section size.

• Cost Warnings Report - Provides a list of warnings for a particular Cost Scenario.
Each of these tabular reports can be sent directly to the printer, or copied and pasted into your favorite
spreadsheet program for further refinement.

10.5.1

Element Detailed Cost Report
This tabular report contains a detailed view of all the cost information entered for a single element. It
includes an itemized list of all the construction and non-construction costs for an element, as well as the
subtotals and total cost of the element. This report is only available for elements that have been selected for
inclusion in the cost calculation.
See the Tabular Report Window for information about exporting and printing the data in this report.
To access the field Element Detailed Cost Report:
Stand-Alone:

Double-click the element for which you wish to see the report, or right-click the
element and select Edit from the drop-down menu. In the dialog that appears,
click the Report button and select Cost Report from the menu.

AutoCAD R14:

Pick the Select tool and click the element you wish to edit. If the Right-Click
Context Menu option is enabled, you can also right-click the element and select
Edit from the drop-down menu. In the dialog that appears, click the Report
button and select Cost Report from the menu.

AutoCAD 2000:

Pick the Select tool and click the element you wish to edit, or select the element
and choose Edit from the drop-down menu. In the dialog that appears, click the
Report button and select Cost Report from the menu.

AutoCAD 2000i:

Double-click the element for which you wish to see the report, or right-click the
element and select Edit from the drop-down menu. In the dialog that appears,
click the Report button and select Cost Report from the menu.

Chapter 10 – Cost Estimating

10.5.2

165

Project Detailed Cost Report
This tabular report contains a detailed view of all the cost information entered for every element included in
the cost analysis. It includes an itemized list of all the construction and non-construction costs for each
element, as well as the cost adjustments made to the total cost of the project. This report is only available
after the costs have been computed for the scenario.
See the Tabular Report Window for information about exporting and printing the data in this report.

10.5.3

Project Element Summary Cost Report
This tabular report provides a summary view of all the cost information entered for each element selected
for inclusion in the cost analysis. It contains an overview of the costs assigned to each element, and an
itemized list of the cost adjustments. This report is only available after the costs have been computed for
the scenario.
See the Tabular Report Window for information about exporting and printing the data in this report.

10.5.4

Project Summary Cost Report
This tabular report provides a summary view of all the cost information entered for the elements selected
for inclusion in the cost analysis. This report contains an overview of the costs assigned to each element
type and an itemized list of the cost adjustments. This report is only available after the costs have been
computed for the scenario.
See the Tabular Report Window for information about exporting and printing the data in this report.

10.5.5

Pipe Costs Report
This printed report provides a summary of the cost of all the pipes included in the cost analysis. The pipes
are broken down by material and section size. The total length of pipe for each size and material are
reported along with the total cost associated with that group of pipes.

10.5.6

Cost Warnings Report
This report provides a list of all the cost warnings for the selected scenario. You will receive warnings
when you have assigned a Unit Cost Function to a particular element but the attribute value for that element
lies outside of the valid range of data you set for the Unit Cost Function. You need to check these elements
and make sure that the cost data supplied to these elements is applicable.
To open the Cost Warnings Report, open the Cost Manager by selecting Analysis / Compute Costs
from the pull-down menu, or click the
button on the Analysis toolbar. In the dialog that appears, click
the Cost Reports button and select Warnings from the drop-down menu.

Notes

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Chapter 11
Presenting Your Results
11.1 Overview
This chapter covers the various methods that are provided for viewing, annotating, graphing, and reporting
your data and results. It also presents the tools available for generating profiles, and color coding elements
based on any assigned or calculated attribute.

11.2 Element Annotation
Element annotations allow you to display detailed information such as pipe lengths or node ground
elevations, as well as calculated values such as velocity, in your drawing. You can add one or more
annotations for any type of element in the system. Annotations update automatically. For example,
annotations will display newly calculated values and will be refreshed as you change scenarios.
The annotations and their format are defined by using the Annotation Wizard. In Stand-Alone
mode, the annotation format can also be easily modified in the Attribute Annotation dialog,
which opens when you double-click the handle of the annotation text in the drawing, or if you
right click on the annotation and select Edit <Attribute> from the pop-up menu.
Pipe annotations can be aligned with the pipes or displayed horizontally, depending on the Pipe
Text alignment setting specified in the Drawing Options dialog.
You can flip the text from one side of the pipe to the other (reading in the opposite direction) to maintain
readability when the pipe direction on a plot is nearly vertical. By default, the text flips direction when the
pipe direction is 1.5 degrees measured counter-clockwise from the vertical. You can modify this value by
inserting a TextFlipAngle variable in the Haestad.ini file, located in the Haestad directory. The angle is
measured in degrees, counter-clockwise from the vertical.
For instance if you want the text to flip when the pipe direction is vertical, you should add the following
line to the Haestad.ini file:
TextFlipAngle=0.0
Reasonable values fall in the range from 15.0 degrees to -15.0 degrees.
The TextFlipAngle is only applicable to annotations on the plan view.

11.2.1

Attribute Annotation Dialog
To access the Attribute Annotation dialog right click on the annotation and select <Attribute Name>
Annotation from the pull-down menu. Alternatively, in the main view in Stand-Alone mode, double-click
the handle of the annotation text to display the corresponding Attribute Annotation dialog. Here you can

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easily modify the format of that attribute annotation without going through the Annotation Wizard again.
The replaceable parameters "%v" and "%u" represent the attribute’s value and unit respectively.

11.2.2

Annotation Properties
You can access the annotation properties for Profile Annotations by right clicking on an annotation and
selecting Annotation Properties from the pop-up menu. The Annotation Properties dialog allows you to
adjust the orientation of the text as it appears on the drawing screen and the profile window.
You can edit the following fields within the dialog:


Orientation - Set the orientation of the text in relation to the horizontal axis. You can select from
Horizontal, Vertical, and Other orientations. Other is any orientation with a rotation angle not 0 or
90 degrees.



Rotation - Specify the angle in degrees of the text with the horizontal axis.



Justification - Select how the text is justified from either: Left, Right, or Centered.



Leader - Check this box to create a line to be drawn from the text annotation to the item to which it
refers.

• Show Leader Arrow - Check this box to create an arrow on the leader line from the text annotation.
Instead of utilizing the above options you can also choose to Align Text with Pipes for the link
annotations.
Annotation Properties can be setup within a Profile Template to eliminate the need of
reestablishing the same properties every time a new profile is created.
These properties are not available for Plan Annotations.

11.2.3

The Annotation Wizard
You can use the Annotation Wizard to add annotations to the drawing, as well as to remove or modify
existing annotations in the drawing. You can annotate all elements or any subset of elements.
The wizard is divided into three steps:


Select Elements - Select the types of elements to annotate.



Specify Annotations - Specify the set of elements to annotate, the attributes you would like to
annotate, and the format of your notations.



Summary - Summary of the selected annotation settings.

To access the Annotation Wizard, click the Annotation Tool
Element Annotation from the pull-down menu.

on the toolbar, or select Tools /

Annotation Wizard - Select Elements
This step allows you to specify the types of elements you wish to annotate by checking the appropriate
boxes. You may annotate more than one type of element at a time by checking all the desired element
types. If you have already annotated your drawing, you can remove annotations for a particular type of
element by unchecking the corresponding box.
If you decide to turn off the annotations for a particular element type, your annotation settings
will be retained, allowing you to easily toggle annotation back on.

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Annotation Wizard - Specify Annotation
The next step(s) allows you to specify the subset of elements and the attributes you wish to annotate for
each element type. For each element type, you will be presented with a table where you can specify the
attributes you wish to annotate, and the mask for each attribute.


Specify the set of elements… - Choose All Elements from the choice list for annotation to applied to
all elements in the network, or choose a selection set. Click the ellipsis (…) button to access the
Selection Set Manager to edit or add selection sets.



Attributes - Select from a list of all available attributes for the current element type including
calculated values. Click this field, and choose the attributes you wish to annotate by selecting from the
list that appears. Clicking the sideways triangle button will open the categorized Quick Attribute
Selector.



Mask - Customize the way the annotation is displayed. The replaceable parameters "%v" and "%u"
represent the attribute’s value and unit respectively. By default, the mask is set up as follows:
<attribute name>: %v %u.



Initial Placement (Profile Annotation Only) - Specify how the annotation will be offset relative to the
label of the element it is referring to. If the <default> is selected then the annotation will be placed
under the label. To specify a custom offset select Offset… from the pull-down menu and click the
ellipses (…) button to bring up the Offset dialog. In this dialog you can specify the x and y offsets.
Click OK when completed.
When annotating, for example, pipe diameters, the default mask is "Diameter: %v %u". The
default annotation for a 150 millimeter pipe would be "Diameter: 150 mm". By changing the
mask to "%v %u", the resulting annotation would be "150 mm".

Annotation Wizard - Summary
The last step of annotating your drawing is reviewing the choices you have made. If you would like to
make changes at this time, simply click the Back button to return to previous windows in the wizard.
When you are satisfied, click the Finished button to apply the annotations to the drawing.
You can turn annotation visibility on or off by editing the Drawing Options. Your annotation
settings will be retained.
If the Drawing Options are set so that element annotations will not be displayed, clicking the
Finished button in the Annotation Wizard will automatically turn annotations on.
In Stand-Alone mode, you can double-click an annotation element in the drawing to edit the
associated mask.
The Annotation Text Height can be adjusted from the Drawing tab of the Options dialog,
accessed by selecting Tools / Options from the pull-down menus.

11.3 Color Coding
Color Coding allows you to assign colors to elements in the drawing based on a variety of input and output
attributes. For any attribute, you can supply a color scheme or have the application generate one for you.
For example, you can supply a color scheme to display all pipes sizes between 2" and 8" in green, those
between 10" and 24" in blue, and those between 27" and 48" in red.

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To access Color Coding, select Tools / Color Coding... from the pull-down menus, click the Color Coding
button

11.3.1

on the main toolbar, or double-click a color coding legend figure in the drawing.

Color Coding Dialog
At the top of the Color Coding dialog are two tabs, Link and Node. You can set up color coding for both
links and nodes, or just one of the two. The following fields are available:


Attribute - Select the attribute by which you would like to color code, or select <None> to turn color
coding off. By clicking the sideways triangle button you can access the categorized Quick Attribute
Selector.



Selection Set - Choose All Elements from the pull-down list to apply color coding to be applied to all
elements in the network, or choose a selection set to apply color coding to a subset. Click the ellipsis
(…) button to access the Selection Set Manager to edit or add selection sets.



Calculate Range - Automatically determine the minimum and maximum for the specified attribute
and selection set.



Minimum / Maximum - Displays the calculated minimum and maximum values for the specified
attribute in the selection set.



Initialize - Automatically calculate a default color coding range for the specified attribute, based on
the values in your project.
Use the Initialize and/or the Insert buttons to define your color coding map. Then click OK to apply the
specified colors to the appropriate elements.

Color coding legends can be added to any location in the drawing by clicking the Legend
button on the Tool Palette.
Color coding will automatically update as input or results change. For example, after performing
a calculation, colors will update to reflect the newly calculated values.
If the results for the selected attribute are not available, or if all values for that attribute are the
same, automatic range initialization will not be performed. You can enter your own custom
range in this case.
A schematic can have any number of color assignments.
The Quick View window can be used to display a summary of the active link or node color coding
parameters.

11.4 Reporting
11.4.1

Predefined Reports
This application provides several predefined reports that can be used in your projects. This feature makes
report generation a simple point-and-click exercise. Simply select the elements for which you want a report
and send them to your printer.

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The following types of Predefined Reports are available:


Element Details Reports



Element Results Reports



Tabular Reports



Scenario Summary Reports



Project Inventory Reports



Plan View Reports
Detailed reports can be copied to the Windows clipboard in RTF format for use in your favorite
word processing program. Refer to the Print Preview window for more information.

To access the Predefined Reports, select Report from the pull-down menus and select the report of your
choice.

11.4.2

Element Details Report
The Detailed Reports dialog allows you to print detailed reports for all elements or any subset of elements
in the system.
In Stand-Alone mode, from the Detailed Reports dialog, select multiple elements to be printed by holding
down the Shift key or the Control key while clicking with the mouse. Holding down the Shift key will
provide group selection behavior. Alternately, use the Select button to open the Selection Set dialog. This
provides more powerful selection functions. When you are satisfied, click the Print button to output the
selected reports.
You can graphically select elements that you would like to print before opening the Detailed
Reports dialog. This is done by holding down the Shift key and selecting elements, or by
dragging a window around the area of interest. The selected elements will be highlighted in the
list of elements to print when you open the dialog.
You can print a detailed report for a single element without using the Detailed Reports dialog.
Simply open the element editor for the desired element and click the Report button.
In AutoCAD mode, to activate the Detailed Reports dialog, select Report / Element Details from the
pull-down menus. The cursor will change to a pick box, signaling you to choose the elements for which
you would like to view reports. Select elements as you normally would in AutoCAD. Press the Enter key,
and the dialog will appear. While all of the elements in the project are listed, the ones you have selected
are highlighted. You can use the Select button to further edit this list. Click the Print button to output the
selected reports when you are satisfied.
To access the Detailed Reports dialog, select Report / Element Details from the pull-down menus.

11.4.3

Element Results Report
The Element Results dialog allows you to print or preview a single report containing the results for any
number of elements in the system.
From the Element Results dialog, you can select elements to be printed by holding down the Shift key or
the Control key when clicking with the mouse. Holding down the Shift key will provide group selection
behavior. Alternately, use the Select button to open the Selection Set dialog. This provides more powerful

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selection functions. When you are satisfied, click the Preview button to view the selected reports, or click
the Print button to print the selected reports.
You can graphically select elements that you would like to print before opening the Element
Results dialog. This is done by holding down the Shift key and selecting multiple elements, or by
dragging a window around the area of interest. The selected elements will be highlighted in the
list of elements to print when you open the dialog.
When working with large systems, the preview option can require a great deal of system
resources. You can reduce resource requirements by selecting a small subset of elements with
which to work. The print option has lower system resource requirements than the preview
option.
In AutoCAD mode, to activate the Element Results dialog, select Report / Element Results from the
pull-down menus. The cursor will change to a pick box, signaling you to choose the elements for which
you would like to view reports. Select elements as you normally would select them in AutoCAD. Press the
Enter key, and the dialog will appear. While all of the elements in the project are listed, the ones you have
selected are highlighted. You can use the Select button to further edit this list. Click the Print button to
output the selected reports when you are satisfied.
To access the Element Results dialog, select Report / Element Results from the pull-down menus.

11.4.4

Tabular Reports
Using the powerful FlexTables feature you can very quickly generate a tabular report containing any
attribute and any network element.
All tabular data in this program can be copied to the Windows Clipboard by right-clicking the
desired table and selecting Copy from the pop-up menu. You can then paste this data into your
favorite spreadsheet or word processor to generate custom reports and graphs.

To access the Table Manager, click the Tabular Reports button
Report / Tables from the pull-down menus.

11.4.5

on the main toolbar or choose

Scenario Summary Report
The Scenario Summary provides a detailed report of the active scenario, including alternatives, and a brief
summary of the calculation options.
To access the Scenario Summary Report, select Report / Scenario Summary from the pull-down
menus.

11.4.6

Project Inventory Report
The Project Inventory report provides a detailed report that includes a summary of the active scenario, a
network inventory, and a detailed pipe inventory (grouped by pipe section).
To access the Project Inventory Report, select Report / Project Inventory from the pull-down menus.

11.4.7

Plan View Report
Generate reports for the plan view of the network, for either the current drawing display (Current View) or
the entire drawing extents (Full View).

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To generate a preview of the report for the current view or the entire network, choose either Report / Plan
View / Current View or Report / Plan View / Full View, respectively, from the pull-down menus.

11.4.8

Calculation / Problem Summary Report
After running hydraulic calculations, the Results tab of the Scenario Editor is displayed. This tab
contains a summary of the calculation results. To view any problems or warnings encountered during the
simulation click the Element Messages button.
Holding the mouse cursor over a message in the Element Calculation Message Browser report
will open up a pop-up message box that displays further information on the message.
The report consists of a series of folders that represent different stages of the calculation process. Double
click a folder or click the + sign to view information related to the folder’s caption. The color of the folder
will indicate if any problems occurred during that portion of the analysis.
The colors indicate the following:


Green light - Calculations were run successfully, without any warning or error messages being
generated.



Yellow light - Calculations were run successfully, without error messages being generated. However,
there are one or more warning messages. Warnings are displayed in the results summary in this tab.



Red light - Calculations were not run successfully and error messages were generated, as shown in the
results summary of this tab.
This report can be previewed before being printed or copied to the clipboard by clicking the Printer button
on the Results tab. It can also be exported to a text file by clicking the Save button on the Results tab.
Only the exposed text will be exported, copied or printed.
The Results tab is accessed from the Scenario Manager, reporting the results corresponding to the
highlighted scenario in the scenario tree view. It can also be accessed for the currently active scenario by
clicking the GO button, which opens the Scenario Editor.

11.5 Graphing
11.5.1

Graph Setup
The Graph Setup dialog allows you to view and compare data for time-based attributes for multiple
elements over multiple scenarios within the hydraulic network. It is accessed either when you select
Element Graph / <Element Type> or Hydrograph from the Report pull-down menu.
The Graph Setup dialog is divided into three or two tabs depending on whether you selected Hydrograph
Report.


Graph Setup - From this tab you can select the dependent variable to be graphed against time. This
tab is not available when graphing hydrographs, as flow is automatically the dependent variable.



Elements - From this tab you can select which elements to include in the graph. There are three ways
to select these elements:


You can check each of the elements you wish to include in the graph in the Available
Elements list.



You can click the Select button and choose the elements by using the Selection Set dialog.

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11.5.2

You can graphically select elements that you would like to print before opening the Graph
Setup dialog. In Stand-Alone mode, holding down the Shift key allows you select multiple
elements. You can also select elements by dragging a window around the area of interest.
The selected elements will be highlighted in the list of elements for graphing when you open
the dialog, when you open the Graph Setup dialog through the Reports menu.

Scenarios - From this tab you can select which scenarios to use when graphs are generated from a list
of scenarios with calculated EPS results.

Graph Window
The Graph window is divided into two tabs: Graph and Data. The Graph tab displays a plot of the
selected dependent variable vs. time. The Data tab will display the data under the Graph tab in a tabular
format.
The following functions will either be formed on the plot or the tabular data depending on which tab is
selected.


Copy - Copies the graph / data onto the Windows Clipboard for use in other applications.



Print - Outputs the contents of the Graph/Data tab to the printer.



Options / Graph Options - Allows you to customize the plot by changing the graph’s axes, fonts,
titles, etc. This is only available when the Graph tab is selected.



Options / Graph Setup - Allows you to rebuild the graph with different data and parameters.



Close - Close the Graph window.

• Help - Provides access to help for the Graph window.
The graph window is accessible whenever you plot time-based data through the Graph Setup dialog.

11.5.3

Plot Window
The Plot window provides the following functionality:


Copy - Copies the plot onto the Windows Clipboard for use in other applications.



Print - Outputs the contents of the Plot window to the printer.



Options / Graph Options - Allows you to customize the plot by changing the graph’s axes, fonts,
titles, etc.



Close - Close the Plot window.

• Help - Provides access to help for the Plot window.
The plot window is accessed whenever you generate non-time based plots such as cost function curves or
pump curves, or whenever you plot input data such as loading patterns.

11.5.4

Graph Options
These features allow you to customize the way a graph or pie chart looks. The dialog is divided into
several tabs:
Titles


Titles - There are three sets of titles for a graph: Graph title, X-Axis title and Y-Axis title. Each title
set contains two levels: title and subtitle. A pie chart simply has a title and a subtitle.

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Title Font - This feature allows you to select and change the text font type for specific items on the
graph or pie chart. Use the selection list to choose the item for which to change the font, then click the
ellipsis (…) button to select the desired font type from the list of available fonts currently installed on
your PC.

Axis (for graphs only)


Automatic Scaling - By default, the program uses the Automatic Scaling options for setting the X and
Y-axis minimum, maximum, and increment values. To customize an axis, turn the check mark off and
enter the desired values for the minimum, maximum, and increment. If desired, you can customize a
single axis while leaving the other in the Automatic Scaling mode.



Log Scale - Place a check mark in this box to use a log scale for this axis. You can use a log scale for
one or both axes.

Grid (for graphs only)


X-Axis - Place a check mark in this box to view grid lines corresponding to the X-Axis labels.



Y-Axis - Place a check mark in this box to view grid lines corresponding to the Y-Axis labels.



Line Color - Use this selection list to define the color to use for both axes grid lines.



Line Style - Use this selection list to define the line type (solid, dashed, etc) to use for both axes grid
lines.



Fill Color - Use this selection list to define the color to use for background fill within the plotting
boundaries of the graph.



Save as Default - Place a check mark in this box to save the current grid settings as the default for
subsequent graphs.
You can specify to use grid lines for one or both axes.

Display (for pie charts only)


Data Labels - Allows you to annotate pie charts with percentages, labels, or both.



Percentages - Indicates how many decimals are to be displayed for the percentage figures.



Legend Location - Allows you to place the legend (if any) on the left, right, top, or bottom of the pie
chart.



Chart View - Allows you to generate a 3D-view pie chart.

Legend


Show Legend - A check mark designates that the legend will be included on the graph or pie chart.
Turn the check mark off if you do not wish to show the legend.



Series - Each series represents a different curve on the graph or a slice on the pie chart. If the graph
contains only one curve, or the pie chart contains only one slice, then it is designated as Series 1.
Scroll through the list and select the desired curve or slice (series number). Then, use one of the
options below to customize it:


Label - Name for the selected curve (series).



Line Color - Color for the selected curve (series).



Line Style (for graphs only) - Style for the selected curve (series).



Line Width (for graphs only) - Width for the selected curve (series).

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Symbol (for graphs only) - Data point symbol to use for the selected curve (series).



Save as Default - Place a check mark in this box to save the current legend settings as the default for
subsequent graphs.
Access the Graph Options by clicking the Options button at the top of a Plot or a Graph Window.

11.6 Pie Charts
Pie charts can be generated for the following, at any node:


Base Load - Shows the components of the sanitary loads entered at a node. This type of pie chart is
available for manholes, junction chambers, pressure junctions, and wet wells.



Sanitary (Dry Weather) Flow - Shows the components of the system sanitary flow at a node.



System Flow Summary - Shows the components of the total flow at any gravity node.

• Total Cost - Shows the components of the total costs for a given scenario.
You can create a Sanitary Flow or System Flow Summary pie chart after calculations have been run.
Open a node's Element Editor, click the Report button, point to the Pie Chart option, and then select the
desired option.
The Base Load pie chart is obtained by opening a node's Element Editor, selecting the Loading tab, and
clicking the Pie Chart button at the right.
You can create a Total Cost pie chart by opening the Cost Manager, right-clicking the desired scenario,
and selecting the Graph option.

11.7 Profile
A profile is a graphical cross-section of a portion of your sewer system. The Profile view shows
information such as ground elevation, pipe inverts, crowns, sumps, and hydraulic grade.
To access Profiling, click the Profile button
on the main toolbar, or choose Tools / Profiling… from
the pull-down menus, or right-click the element from which you would like to begin profiling.

11.7.1

Profile Manager
Within the Profiles Manager, profile views can be created and accessed. The previously created profile
views will appear in the main pane of the dialog. To view a profile in the list, select it and click the Open
button.
By clicking the Profile Management button the following functions can be performed:


Add - Creates a new profile view.



Edit - Select elements to be profiled and edit the Profile Options for the highlighted profile.



Rename - Renames the selected profile.



Delete - Deletes the selected profile.



Notes - View and edit notes associated with the selected profile.

• Apply Template - Update a profile based on a new (or revised) template.
Click the Templates button to open up the Profile Templates dialog.

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Profile Templates
Profile Templates Dialog
The Profile Templates dialog allows you to create and modify pre-defined templates that can be applied to
new profiles in the first step of the Profile Wizard. The templates will then establish the annotations and
text properties for the new profile, instead of having to reestablish all the information every time you create
a new profile.
The following buttons are displayed on the dialog:


Add - Create a new template. When this button is clicked you will be prompted to name the template.
Click OK to continue to the main Template dialog.



Edit - Modify the existing template selected from the list.



Duplicate - Create a copy of the selected template. When this button is clicked you will be prompted
to name the duplicate.



Delete - Remove the selected template from the list.



Rename - Change the name of the selected template. When this button is clicked you will be
prompted for the new name.

• File - Import and Export templates for use by other users.
To access the Profile Templates dialog click the Templates button on the Profiles dialog.

Templates
A template is a predefined set of text styles and annotations that can be applied to a new profile upon its
creation. By setting up a single template, you can eliminate having to re-setup the generic portions of the
profile every time a new one is created.
The Template dialog is divided into five tabs:


Layout Options - Edit the configuration of the profile text.



Drawing - Edit the drawing scale and the axes labeling



Annotation - View the existing annotation and modify it.



Labels - Edit the profile labels.



Layers - Set up the layer configurations for the template.

Template Layout Options Tab
Under the Layout Options tab you set up the configuration for the pipe and node text for the profile
template. The following options are identical for both node and pipe elements:


Orientation - Set the orientation of the text in relation to the horizontal axis. You can select from
Horizontal, Vertical, and Other orientations. Other is any orientation with a rotation angle not 0 or
90 degrees.



Rotation - Specify the angle in degrees of the text with respect to the horizontal axis.



Justification - Select how the text is justified from either: Left, Right, or Centered.



Leader - Check this box to create a line from the text annotation to the item to which it refers.



Show Leader Arrow - Check this box to create an arrow that will appear on the leader line from the
text annotation.

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Instead of utilizing the above options you can also choose to Align Text with Pipes for the pipe
annotations.
These same options are available for individual annotations on the Profile Window by right
clicking on one of the annotations and selecting Annotation Properties from the pop-up menu.

Template Drawing Tab
Under the Drawing tab you can set various options associated with the drawing scale and axes labeling to
be specified in the template. The Drawing tab of the Template dialog has the following sections:


Drawing Scale - In this section you can choose to set the scale based on the project scale by checking
the Match Project check box. If the box is unchecked then you can specify your own horizontal and
vertical scales as well as the default text height multiplier.



Axis - In this section you can specify the horizontal and vertical increment for the axis labeling, as well
as the position of the elevations on the Y-axis. For example, if you choose Left from the Axis
Labeling drop-down menu then labels will appear on the left side of the profile. You can choose for
the labels to also appear on the right side of the profile or on both sides of the profile.

Template Annotation Tab
Under the Annotation tab you can view the annotations selected for the current template, as well as each
annotation’s initial placement.
To open the Annotation Wizard to edit the template annotations click the Edit button.

Template Labels Tab
Under the Labels tab you can specify various labels associated with the profile, as well as an associated
height multiplier.
In the label fields you can put one of several dynamic parameters that will automatically update as the
model updates. The following table shows the list of available parameters and an example of their use.

Dynamic
Parameter

Function

Label Input
Example

Label Output Example

%s

Displays the name of the
current scenario in the label.

Scenario: %s

Scenario: Base

%p

Displays the profile name.

Profile: %p

Profile: Trunk Line

%t

Displays the current time step
for the scenario.

Scenario: %s (%t)

Scenario: Base (0.00 hr)

%u

Displays the units of the
appropriate attribute.

Station (%u)

Station (ft)

Template Layers Tab
From the Layers tab you can set various properties for the different layers associated with a hydraulic
profile. You can click whether or not the layer is visible. You can also set the color for the layer. If you
click the ellipses (…) button from inside one of the Color fields you can select or create a customized
color.

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The properties established for the layers will remain if the profile is exported to a DXF or directly to
AutoCAD.

Sharing Templates Between Projects
All template information created at a computer is stored in the file called ProfileTemplates.LTM, located in
the product directory. So if you create several templates types that you wish to share between different
users, simply transfer the file to the other machines with the product installed, and copy over the existing
profile templates file.
Alternatively, you can export individual profile templates for import by other users by clicking the File
button on the Template Manager dialog and selecting Export Template from the pop-up menu. This
creates an .LTF file with a saved copy of the selected template.
To import the template, select Import Template after clicking the File button in the Template Manager.
This will copy the template data to the ProfileTemplates.LTM file on that machine for reuse.

11.7.3

Profile Wizard
The Profile Wizard is provided to guide you through the profile generation process. You will be asked to
specify a profile start and stop node, as well as the horizontal and vertical axis scaling parameters.
Profile Wizard - Profile Elements
The first step of the Profile Wizard allows you to specify the elements included in the hydraulic profile.
The specified elements will appear in the list pane in the dialog. You can modify the list by clicking the
following buttons:


Select From Drawing - Clicking this button will open the plan view of the hydraulic network. Simply
click the elements you wish to include in the profile. The profile must consist of a single path that can
go from upstream to downstream or downstream to upstream or in both directions. The elements can
include both gravity and pressure elements. Right click and select done when finished. In AutoCAD
mode simply click the drawing pane to return to the Profile Wizard.



Remove All - This will delete all the elements from the profile list.



Remove All Previous - This will delete all elements above the selected element in the list.

• Remove All Following - This will delete all the elements below the selected element in the list.
In the first step of the Profile Wizard, you can also establish user-defined stationing for the node elements
in the profile, and weather the calculated Stationing Order is increasing or decreasing.
To establish a user-defined station for a node in the list, click the User Defined Station checkbox in the
row occupied by the node. All stationing upstream of that node will be recalculated based on the entered
station if they are not specified as user defined.
Profile Wizard - Templates and Notes
The second step of the Profile Wizard allows you to specify the template to be applied to the new profile.
Select it from the Template pull-down menu. Click the ellipses (…) button next to the Template pulldown menu to open up the Profile Templates dialog. You can also enter any notes about the profile in the
large text box below the notes icon.

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Templates are only used initially when defining the profile. Once the profile is created all
connections to the selected template are severed. Therefore if you change a characteristic of the
template the change will not be reflected in the profile. This prevents undo modification.
You can reapply a template through the Profiles dialog. Click the Profile Management button
and select Apply Template.
Profile Wizard - Options
The third step of the Profile Wizard allows you to customize the horizontal and vertical axis scaling
parameters. You can choose either automatic or user-defined axis scaling. Use automatic scaling to accept
the default scale for the profile axis. Choose user-defined scaling to specify the axis minimum, and
maximum values. The increment value is accessible regardless of which option is selected. You can also
set the direction of the profile either from left to right or from right to left.
The Profile Wizard can be accessed by clicking the Profile button
, and then clicking the Profile
Management button and selecting add. You can also right-click the node from which you would like to
begin profiling, and select Profile from the pop-up menu. In AutoCAD mode, this requires you to have the
Right-Click Context Menu toggled On in the Global Options dialog, which is accessed from Options /
Global Options.

11.7.4

Profile Window
The profile that you specified will be displayed in the Profile Plot window. The following functions are
available in the main toolbar.


File / Export to Drawing - (AutoCAD mode only) Export the file to your AutoCAD drawing.



File / Export to DXF - Export the profile in a .DXF format for use in AutoCAD.



Undo / Redo - Click the left facing arrow to undo the previous command. Click the right facing arrow
to redo the command.



Pan - Move around in the profile window.



Zoom Support - Zoom in, Zoom Out, Zoom Extents, and Zoom Window.



Options - Opens the menu with the following items


Find Element - Locate an element in the Profile Window.



Profile Options - Set Axis and Drawing options and various other user-specified parameters.



Annotation Manager - Set annotations for the elements in the profile.



Print Preview - Preview the Profile view.



Close - Exit the Profile window. Any edits made in the Profile window will be lost when you exit.

• Help - Opens the program's Help database.
In addition to the functions on the main toolbar, you can add your own text and graphic annotations to the
profile by clicking the representative buttons on the vertical side-toolbar of the Profile Plot window.

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You can make adjustments to your profile options after generating the profile by using the
Options button at the top of the Profile Window.
You can use the mouse to graphically drag and reposition the textual annotations in the Profile
window.
The Hydraulic and Energy Grade Lines will only be plotted if the calculated results are valid.
You may need to Compute your model to make sure the results are valid.
Use the scroll bars along the right and bottom of the Profile window to pan left, right, up, and
down.
Edit the outlet element to change the starting station used in profiling.
Use the Scenario control located at the top of the Profile window to see the profiles for different
scenarios.
Use the VCR Controls to animate the hydraulic grade line for an EPS analysis.

The Profile window is accessed by clicking the Profile button
and opening an existing profile in the
Profiles Manager. The Profile Window will also appear after completing the Profile Wizard.

Profile Options Dialog
The Profile Options dialog allows you to customize the horizontal and vertical axis scaling parameters, the
line widths, text height, and layer visibility. The dialog is divided into four tabs:


Elements tab - This tab is only available when you open the profile options by selecting Profile
Management / Edit from the Profiles dialog.



Axis tab



Drawing tab



Layers tab



Background tab

Profile Elements Tab
Within the Elements tab you can specify the elements to include in the hydraulic profile. The specified
elements will appear in the list pane in the dialog. You can modify the list by clicking the following
buttons:


Select From Drawing - Clicking this button will open the plan view of the hydraulic network. Simply
click the elements you wish to include in the profile. The profile must consist of a single path that can
go from upstream to downstream or downstream to upstream or in both directions. The elements can
include both gravity and pressure elements. Right click and select done when finished. In AutoCAD
mode simply click the drawing pane to return to the Select Elements dialog.



Remove All - This will delete all the elements from the profile list.



Remove All Previous - This will delete all elements upstream of the selected node.



Remove All Following - This will delete all the elements downstream of the selected node.

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You can also establish user-defined stationing for the node elements in the profile, and weather the
calculated Stationing Order is increasing or decreasing.
To establish a user-defined station for a node in the list, click the User Defined Station checkbox in the
row occupied by the node. All stationing upstream of that node will be recalculated based on the entered
station if they are not specified as user defined.
To access the Profile Elements tab, click the Profile Management button in the Profiles dialog and click
Edit. Then click the Profile Elements tab.

Profile Axis Tab
The Axis tab allows you to customize the horizontal and vertical axis scaling parameters. You can choose
automatic or user-defined axis scaling. Use the automatic scaling to accept the default scale for the profile
axis. Choose user-defined scaling to specify the axis minimum, and maximum values by deselecting the
Automatic Scaling check box. You can also select the position of the labeling on the vertical axis. For
example, if you select Left from the Axis Labeling drop-down menu, the elevation labels on the Y-axis
will appear on the left hand side of the profile. You can also choose for the labels to appear on the right
side of the profile, as well as on both sides of the profile.
Under the Axis tab you can also set the direction of the profile in the Direction field

Profile Drawing Tab
The Drawing tab allows you to set line widths for some of the profile figures, toggle layer visibility, and
adjust the size of the text in the profile.
To change the line widths for the ground elevation, the node structures, and the hydraulic grade and energy
grade lines in the profile, simply enter the desired size in their respective fields.
The Text Height Annotation Multiplier allows you to adjust the size of the text in the profile.
You can also adjust the line widths for various graphic attributes presented on the profile such as:
Ground Elevation
Structures
Hydraulic Grade
Energy Grade

Profile Layers Tab
From the Profile Layers Tab you can set various properties for the different layers associated with
hydraulic profile. You can click whether or not the layer is visible. You can also set the color for the layer.
If you click the ellipses (…) button from inside one of the Color fields you can select or create a
customized color.
The properties established for the layers will remain if the profile is exported to a DXF or directly to
AutoCAD.

Profile Background Tab
A .DXF image can be inserted as a background for the selected profile.


DXF Background Filename - This field enables you to specify a .DXF file to be used as the
background for your project. Enter the drive, directory, and file name, or click the Browse button to
select a file interactively.



Show Background - If the background .DXF file is turned off, it will not be read from a disk or
displayed in the drawing pane.

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DXF Unit - The .DXF drawing unit conversion is used when importing .DXF background files, and
also when exporting a .DXF file from the project. Note that the value in this field governs the import
behavior for .DXF files saved in scientific, decimal, or fractional units, but not for .DXF files saved in
architectural or engineering units.



Insertion Point - These fields enables you to specify the point (X and Y coordinates) in the profile
where the drawing will be inserted.
.DXF file import behavior is governed by specific factors within the .DXF file. If a file does not import as
you expect, check the options used to generate it carefully. For example, try importing the .DXF back into
the original program or into another program that supports the .DXF format, such as AutoCAD or
MicroStation. If the file does not import into other applications, there may be an invalid or missing header,
invalid elements, or other errors.

Export Profiles
In AutoCAD mode, profiles can be exported to an AutoCAD drawing using the File menu on the Profile
Window. Profiles will be exported to an insertion point below the current drawing extents.
In Stand-Alone mode, profiles can be exported into a .DXF file. After performing a few preliminary steps
you can import the file into AutoCAD.

11.8 Diversion Network
The Diversion Network window provides a graphical view of the diversion links in the system. The flow
arrows on the links in the diversion network indicate the directions of diverted flow. The diversion network
is displayed with the existing network as the background.
After the model is calculated, diversion links will be annotated with the percent diverted out.

11.8.1

Diversion Network Window
The diversion network will be displayed in the Diversion Network window. The following functions are
available in the Diversion Network window:


File / Export to DXF - Export the network in a .DXF format for use in AutoCAD.



File / Export to Drawing (AutoCAD mode only) - Export the network into your AutoCAD drawing.



Pan - Moves around the diversion network to change view.



Zoom Support - Zoom in, Zoom Out, Zoom Extents, and Zoom Window.



Options - Toggle background visibility, set background color, and find elements.



Print Preview - Preview the network.



Close - Exit the network window.
You can specify the diversion target on the Diversion tab of the element's editor.
Use the scroll bars along the right and bottom of the Diversion Network window to pan up, down,
left, and right.
Use the Scenario control located at the top of the Diversion Network window to see the gutter
network for different scenarios.

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Diversion Network Options
The Options button located at the top of the Diversion Network window allows you to change the color of
the background drawing, toggle the visibility of the background drawing, and find elements.

11.8.3

Diversion Network Background Color
This dialog allows you to optionally display your background drawing in a single color. To display the
background in a single color, select the desired color from the list. To display the background using the
current background drawing colors select <Auto>.

11.9 Scenario Comparison
The data calculated in different scenarios can be compared through the use of the Scenario Comparison
window. This allows you to create an annotated drawing to display the differences in the values for any
two scenarios.

11.9.1

Annotation Comparison Wizard
The Annotation Comparison Wizard is used to create a drawing that contains text elements displaying
the differences between specific attributes of two scenarios. The Annotation Comparison Wizard is
identical to the Annotation Wizard except it has one additional step. This step involves selecting the two
scenarios you wish to compare.


Scenario 1 - Choose the baseline scenario.

• Scenario 2 - Choose the scenario you wish to compare to Scenario 1.
The value in Scenario 1 is subtracted from the value of Scenario 2, and the difference is displayed.
Therefore, if any specified attribute’s value is greater in Scenario 2 than it is in Scenario 1, the difference is
displayed as a positive number. If the value is smaller in Scenario 2 than in Scenario 1, it is displayed as a
negative number.
For example, suppose your model contains two scenarios. One is named 2002 Conditions, and the other is
named 2010 Conditions. To create a drawing that displays the difference in velocity in a pipe between the
2002 scenario and the 2010 scenario, you would use the Annotation Comparison Wizard. You could
choose the 2002 scenario as Scenario 1, and the 2010 scenario as Scenario 2. You would then complete the
rest of the steps in the wizard. The drawing produced would show positive values where the velocity
increased under 2010 conditions and negative values where the velocity decreased under 2010 conditions.
For applications that support extended period simulations, you can choose the same scenario for
Scenario 1 and Scenario 2 to annotate the differences between two time steps of that scenario.
To access the Annotation Comparison Wizard, open the Scenario Manager and click the Scenario
Comparison button.

11.9.2

Scenario Comparison Window
The Scenario Comparison window allows you to view, print, export, and modify scenario comparison
annotations.
Along the top of the window is a row of buttons that perform the various functions listed below:


File / Export To DXF - Exports the drawing in the standard .DXF file format.

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File / Export To AutoCAD (available only in AutoCAD mode) - Export the drawing to the current
AutoCAD drawing.



Zoom Tools - Provides standard zoom capabilities for navigating within the drawing.



Options / Annotation Manager - Opens the Annotation Comparison Wizard to add, delete, or
modify the scenario comparison annotations.



Options / Annotation Height Multiplier - Modifies the text height for the scenario comparison
annotations.



Options / Find Element - Allows you to locate an element by its label.



Print Preview - Opens the Print Preview window to view how the printed page(s) will look.



Close - Closes the Scenario Comparison window.

• Help - Get quick access to this Help topic.
Several user interface elements are available to let you modify the scenarios that are being compared, and
to control when the scenario comparison annotations are updated. These interface elements are described
in more detail below.


Scenario 1 - This row of controls is similar to the Analysis Toolbar on the main window. This field
allows you to choose, from the list of available scenarios, the one that will be the baseline in the
comparison.



Scenario 2 - This row of controls is identical to those described above in Scenario 1, but instead of
defining the baseline for the comparison, the scenario you pick here will be compared to the baseline.



Update - Click this button to refresh the scenario comparison annotations. This button is used when
Auto Update (described below) is off, and you have changed either Scenario 1 or Scenario 2.



Auto Update - A check in this box indicates that Auto Update is on, and that the scenario comparison
annotations will be refreshed whenever Scenario 1 or Scenario 2 is changed. With Auto Update off,
you can select the desired combination of Scenario 1 and Scenario 2, then click the Update button.
With Auto Update on, the annotations will refresh automatically to every scenario or time step
change.
The Scenario Comparison window is accessed by clicking the Scenario Comparison button in the
Scenario Manager, and then completing the Annotation Comparison Wizard.

11.10 Graphic Annotation
In Stand-Alone mode, several Graphic Annotation tools are provided for enhancing the appearance of
your drawing. Graphic annotations can be manipulated like any other element in the Graphical Editor.
You can add, move, and delete them just as you would with any network elements.
To add graphic annotation to your drawing, use the Tools\Layout / Graphic Annotation menu item, or
use the tool-palette located along the left side of the main window. The available tools are:


Line Tool - Add polylines or polygons such as drawing roads or catchment outlines.



Border Tool - Add rectangles to your drawing for creating borders such as property lines.



Text Tool - Add text to your drawing for adding explanatory notes, titles, or labels for non-network
elements.

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The program will calculate the area of a closed polyline. Right-click the polyline for which you
wish to determine the area and select Enclosed Area.
To open or close a polyline, right-click the polyline and select Close. A check will appear next to
the menu item to indicate that the polyline is closed.
To add bends or vertices to a polyline, right-click the polyline at the location you would like to
add a bend and select Bend/Add Bend.
To remove bends or vertices from a polyline, select the polyline, right-click the bend you would
like to remove, and select Bend/Remove Bend.

11.10.1

Legend
Legends are used to display the ranges of the active link and node color coding. The legend tool adds a
color coding legend to the drawing. This legend is automatically updated as the color coding is modified.
Editing of the legend figure is not required. In Stand-Alone mode, multiple legends may be placed in the
drawing to assist you when printing specified regions within the drawing.
You can double-click a color coding legend in the drawing to edit the associated color coding
parameters.

11.11 Preview Windows
This window provides you with a preview of what will be printed. The window contains the following
buttons:


Pg Up / Pg Dn - Navigate between pages of the report.



Copy - Copy the report(s) to the Windows Clipboard.



Print - Output the report to the printer.



Options


Print Setup- Change printer options, such as portrait or landscape page layout.



Fit to Page - The Fit to Page check box will not appear if the Print Preview window does not
contain a drawing, or if the drawing is in schematic mode. When checked, the drawing will be
scaled to fit within a single page. When not checked, the drawing will be output using the
drawing scale.



Close - Close the Print Preview window.



Help - Provides access to help for the Print Preview window.

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11.12 Status Log
Several commands generate a status log showing the results of that command. For instance, a status log is
displayed when you calculate a scenario using the GO button. The status information is displayed at the
top of the dialog. The dialog contains the following buttons:


Save - Export the status log results as an ASCII file.



Print or Print Preview - Print or preview the status log results.



Close - Close the status log dialog after design calculations.



Help - Access context-sensitive online help.

Notes

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Chapter 12
Engineering Libraries
12.1 Engineering Libraries Overview
The Haestad Methods' Engineering Libraries and Library Managers are powerful and flexible facilities
for managing specifications of common materials, objects, or components that are shared across projects.
Some examples of objects that are specified through engineering libraries include pipe materials, pipe
sections (in StormCAD and SewerCAD), and sanitary loads (in SewerCAD only). You can modify
engineering libraries and the objects they contain by using the Tools / Engineering Libraries option, or by
clicking the ellipsis (…) buttons available next to the fields in dialog boxes that make use of library objects.
The data for each engineering library is stored in a tabular ASCII file with the extension .HLB.
We strongly recommend that you only edit these files using the built-in facilities available by
selecting Tools / Engineering Libraries. If absolutely necessary, these library files may be edited
or repaired using any ASCII editor.
The standard set of engineering libraries shipped with your Haestad Methods product reside in the
product’s program directory. By default, each project you create will use the objects in these default
libraries. In special circumstances, you may wish to create custom libraries to use with one or more
projects. You can do this by copying a standard library or creating a new library, and setting the path in the
Engineering Library Manager to the path for the custom library.
When you change the properties for an object in an engineering library, those changes will affect all
projects that use that library object. At the time a project is loaded, all of its engineering library objects are
synchronized to the current library. Objects are synchronized based on their label. If the label is the same,
then the object’s values will be made the same. If any library referenced in a Library Manager path
cannot be found at the location specified, then the standard library in the program directory will be used.
Once a project is created, it is not necessary to have access to the engineering library in order for that
project to be edited or analyzed.

12.2 Engineering Library Manager
The Engineering Library Manager dialog consists of a table of five columns: Library, Current Path,
Browse, Edit, and New. There is one row for each kind of engineering library used in your project. You
cannot create library types different from the set of standard libraries shipped with the product. The
columns in the table are as follows:


Library - This column lists the kind of object stored in the referenced library.



Current Path - This column lists the path to the library to be used for objects of a certain kind within
the current project. By default, the path will reference the standard library shipped with your Haestad
Methods product. To browse for other libraries of the same type that you may have already created,
click the Browse column.

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Browse - Click this column and the button that appears if you wish to search your computer or
network and locate other engineering libraries. To reference a library in the path field, the library must
already exist. To create it you may copy a standard library using Windows File Manager or Explorer,
or click New as described below.



Edit - Click this column and the button that appears if you wish to add, delete, or edit the objects
within a specific kind of engineering library.



New - Click this column and the button that appears if you wish to create a new library.
Most users do not need to create custom libraries or edit the library paths. You only need to
change path values if you wish to create and use custom libraries.

The Engineering Library Manager can be accessed by selecting Tools / Engineering Libraries from the
pull-down menus.

12.3 Engineering Library Editor
The Engineering Library dialogs consist of a table with two columns:


Label - This column contains a textual description of the object. In general, objects are considered to
be the same if their labels are the same. For example, when a project is loaded, the engineering library
objects are synchronized to the current library based on label.



Available in ... - This column contains a checkbox indicating whether the library object on the given
row is enabled for use by this application. If an object is enabled, it will appear in choice lists as a
candidate for use in the project. If an object is disabled, it will remain in the library and be editable,
but it will not be offered as a candidate for any operations in the program. If a disabled object has
already been used in a project, then it will remain in use. Disabling it will not affect the existing
project in any way.
The following command buttons appear on the Engineering Library dialog:


Insert - Insert a new, unlabeled object into the current library. You must then click the Edit button to
edit the label and add the appropriate values before the library will be valid. Library objects will be
sorted by label in ascending alphabetical order the next time you open the Engineering Library
dialog.



Duplicate - Create a copy of the currently highlighted object at the bottom of the list.



Delete - Delete the object represented by the highlighted row. Note that this command always deletes
objects from the library, but never deletes an object from your current project if it is in use. To change
the library object that is currently in use by a project, proceed to the dialog containing the field where
the library object is referenced and select a different library object.



Edit - Access the object properties editor.



Usage - Only applies to the material engineering library. Use this button to specify specific uses for
the material.
The Engineering Library Editors can be accessed by selecting Tools / Engineering Libraries from the
pull-down menus and clicking the Edit column and the button that appears next to the Library you want to
edit.

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12.4 Usage
This dialog only applies to the Material Library. Usage is what specifies the type of section or pipe that
will be available for each material. Use the following commands to select which sections you would like to
be available for each material:


[ > ]

Adds the selected item(s) from the Available Items list to the Selected Items list.



[ >> ]

Adds all of the items in the Available Items list to the Selected Items list.



[ < ]

Removes the selected item(s) from the Selected Items list.



[ << ]

Removes all items from the Selected Items list.

12.5 Extreme Flow Factor Method Library
Extreme flow factors are generally used for computing peak discharges, and therefore are typically referred
to as peaking factors or peaking equations. However, since they can also be used to compute minimum
discharges, the term extreme flow factor is more accurate and will be used throughout the program and
documentation.
SewerCAD defines tabular and equation extreme flow factor methods in the editable Engineering
Libraries, thus allowing you to edit predefined methods and insert new ones. The extreme flow factor can
be user-defined with either of the following:


Equation extreme flow factor method

• Table extreme flow factor method
In both cases, the extreme flow factor method can be a function of either of the following:


Contributing population



Base Load
Discharge based extreme flow methods can be used with any unit dry load. Population based
extreme flow methods can be used only with population-based unit sanitary and non-populationbased unit sanitary loads that have population equivalents specified.

12.5.1

Extreme Flow Factor Equation Properties
SewerCAD uses a generic exponential equation to define any extreme flow factor method. For populationbased extreme flow factor methods, the generic equation is:

EFF = c1 +

c 2 + (m1 + P) e1
c 3 + (m 2 P) e 2

where P is population and c1, c2, c3, m1, m2, e1, and e2, are constants.
For discharge-based extreme flow factor methods the generic equation is:

EFF = c1 +

c 2 + (m 1Q) e1
c 3 + ( m 2 Q) e 2

where Q is total sanitary (base) load and c1, c2, c3, m1, m2, e1, and e2, are constants.

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The Extreme Flow Factor Equation Method is defined by the following:


Label - The name of the extreme flow factor method as it will appear in choice lists.



Function of - The type of extreme flow factor method, population-based or discharge-based,
associated with the equation. The extreme flow setup function is selected when a new extreme flow
factor method is created.



Unit - The unit in which the formula is defined. The coefficients in the equation are dependant on this
unit.



Cutoff Value - The maximum possible extreme flow factor for peaking methods. This is used to
prevent unrealistically high values for small populations or land areas.



Equation coefficients - c1, c2, c3, m1, m2, e1, and e2
You can use the Plot option to see the extreme flow factor method range. Also, use the Notes tab
to enter any information relevant to the equation.

12.5.2

Extreme Flow Factor Table Properties
The Extreme Flow Factor Table Method is defined by:


Label - The name of the extreme flow factor method as it will appear in choice lists.



Function of - Type of the extreme flow factor method, population-based or discharge-based,
associated with the equation. The extreme flow setup function is selected when a new extreme flow
factor is created.



Extreme Flow Factor Table - EFF vs. base load (or total dry weather discharge) values.
Extreme flow factor values that fall outside of the range of boundary values will be assigned the
closest in-range value, either the first (lowest) or last (highest) value. Also, use the Notes tab to
enter any information relevant to the table.

12.6 Section Size
12.6.1

Section Size Library
A listing of typical component sizes for specific material types used in storm and sanitary sewer design is
provided. Occasionally, there may be situations where specific component sizes or types will not be
physically available for a project. You may wish to remove these component types from the listing so that
they are not used during automatic design. Similarly, your project may require a size that is not in the list
provided.
This powerful engineering library system allows you to add and remove section sizes, or edit the properties
of an existing section size. The default list includes hundreds of predefined section sizes in five different
shapes. Each section size can be made available for any of the defined materials.
The five section shapes are:


Arch



Box



Circular

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193

Horizontal Ellipse

• Vertical Ellipse
Section size properties are edited through the Engineering Library Manager and the Engineering
Library Editor.
To access the Section Size Properties dialog, select Tools / Engineering Libraries from the pull-down
menus. Click the Edit column of the Section Size Library, and click the button that appears. Select a
section size from the list, and click the Edit button.

12.6.2

Arch Section Size Properties
The Arch Section Size Properties tab in the Section Size Properties dialog is used to edit the physical
properties for arch sections. These properties control how the section is displayed, and define the hydraulic
parameters used during calculations.


US Label - Enter the label for the section that will be used when the predominant unit system is US
Customary.



SI Label - Enter the label for the section that will be used when the predominant unit system is System
International (SI).



Span - Enter the span (width) of the arch shape.



Rise - Enter the rise (height) of the arch shape.



Full Area - Enter the full cross-sectional area for the arch.



Bottom Radius - Enter the radius for the bottom curve of the arch.



Bottom Distance - Enter the distance from the bottom of the arch section to the pivot point for the top
curve.



Corner Radius - Enter the radius for the corner curves of the arch.

• Top Radius - Enter the radius for the top curve of the arch.
To access the Arch Section Size Properties dialog, select Tools / Engineering Libraries from the pulldown menus. Click the Edit column for the Section Size Library, and click the button that appears.
Choose the desired arch size from the list, and click the Edit button.

12.6.3

Box Section Size Properties
The Box Section Size Properties tab in the Section Size Properties dialog is used to edit the physical
properties for box sections. These properties control how the section is displayed, and define the hydraulic
parameters used during the calculation.


US Label - Enter the label for the section that will be used when the predominant unit system is US
Customary.



SI Label - Enter the label for the section that will be used when the predominant unit system is System
International (SI).



Span - Enter the span (width) of the box shape.



Rise - Enter the rise (height) of the box shape.

• Full Area - The calculated full area for the box.
To access the Box Section Size Properties dialog, select Tools / Engineering Libraries from the pulldown menus. Click the Edit column for the Section Size Library, and click the button that appears.
Choose the desired box size from the list, and click the Edit button.

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Chapter 12 – Engineering Libraries

Circular Section Size Properties
The Circular Section Size Properties dialog is used to edit the physical properties for circular sections.
These properties control how the section is displayed, and define the hydraulic parameters used during the
calculation.


US Label - Enter the label for the section that will be used when the predominant unit system is US
Customary.



SI Label - Enter the label for the section that will be used when the predominant unit system is System
International (SI).



Diameter - Enter the diameter of the section.

• Full Area - The calculated full cross-sectional area for the circular section.
To access the Circular Section Size Properties dialog, select Tools / Engineering Libraries from the
pull-down menus. Click the Edit column for the Section Size Library, and click the button that appears.
Choose the desired circular size from the list, and click the Edit button.

12.6.5

Ellipse Section Size Properties
The Ellipse Section Size Properties dialog is used to edit the physical properties for both horizontal and
vertical ellipse sections. These properties control how the section is displayed, and define the hydraulic
parameters used during the calculation.


US Label - Enter the label for the section that will be used when the predominant unit system is US
Customary.



SI Label - Enter the label for the section that will be used when the predominant unit system is System
International (SI).



Span - Enter the span (width) of the ellipse shape.



Rise - Enter the rise (height) of the ellipse shape.



Full Area - Enter the full cross-sectional area for the ellipse.



a0, a1, a2, a3, a4 - Enter the five coefficients to the 4th order polynomial equation, which describes the
relationship between the wetted perimeter (in inches) of the ellipse and the depth/rise ratio, as follows:

( r )+ a (d r ) + a (d r ) + a (d r )
2

p = a0 + a1 d
Where:



2

3

3

p =

Wetted Perimeter (in)

d =

Water depth in the pipe (ft)

r

Pipe rise (ft)

=

4

4

Equivalent Diameter - Enter the diameter of a circular section that is equivalent to the ellipse.



Flow Area Factor - Enter the flow area factor for the ellipse. This is the ratio of the calculated full
area (π * rise * span / 4) to the specified full area.
To access the Ellipse Section Size Properties dialog, select Tools / Engineering Libraries from the pulldown menus. Click the Edit column for the Section Size Library, and click the button that appears.
Choose the desired ellipse size from the list, and click the Edit button.

12.6.6

Available in Materials
Each section size is available in a variety of materials, which means you only have to define the physical
characteristics of the section once.

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195

This tab in the Section Size Properties dialog is used to specify the materials in which the section size is
available. Just add those materials to the table from the list provided. The list of materials, also accessible
in the Material Library, can also be edited. See the Engineering Library Editor for more details.
Section size materials are edited through the engineering library system by using the Engineering Library
Manager and the Engineering Library Editor.

12.7 Material Properties
12.7.1

Material Library
A customizable library of materials is provided. Pipes are constructed from various materials. It is often
useful to specify the material of the pipes and channels/ditches in your hydraulic and hydrologic models.
Materials provide the pipe or channel with a default value for the roughness coefficient used in the friction
equations. Therefore, a material must be defined with the following properties:


Label - Name of the material as it will appear in material selection lists.



Culvert Inlet Material Type - Limits the type of culvert inlets that are available when the material is
used as the culvert material (used in CulvertMaster). The inclusion of this property allows the sharing
of libraries among Haestad Methods' products.



Manning's Coefficient - Default value for Manning's n. This is a number generally between 0.009
and 0.300.



Roughness Height - Default value for absolute roughness height. This will be used in conjunction
with the Darcy-Weisbach friction equation. The roughness height has units of length, typically mm or
ft.



Kutter's n Coefficient (StormCAD and SewerCAD) - Default value for Kutter’s formula. This is a
unitless number generally between 0.009 and 0.300.



C Coefficient - Default value for Hazen William's C. This is a unitless number generally between 60
and 150.
The check boxes next to each item specify whether the friction method will be available for the material.
For example, some materials, such as asphalt, only have Manning’s n values defined.

12.8 Minor Loss
12.8.1

Minor Loss Properties
An editable library of minor losses is provided. Minor losses are used on pressure pipes and valves to
model headlosses due to pipe fittings or obstructions to the flow. A minor loss is defined with the
following properties:


Label - Name of the minor loss as it will appear in choice lists.



Type - General type of fitting or loss element. This field is used to limit the number of minor loss
elements available in choice lists. For example, the minor loss choice list on the valve dialog only
includes minor losses of type valve. You cannot add or delete types.



K Coefficient - Headloss coefficient for the minor loss. This unitless number represents the ratio of
the headloss across the minor loss element to the velocity head of the flow through the element.

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12.9 Unit Sanitary (Dry Weather) Load
SewerCAD defines unit sanitary loads in editable Engineering Libraries, allowing you to edit predefined
unit sanitary loads and insert new ones. A unit sanitary load is used to specify loads to a sewer system for a
user-selected loading unit. Unit sanitary loads can be either population-based or non-population-based.
Population-based unit sanitary loads specify a load to the sewer system as a function of the contributing
population. Non-population-based loads specify loads based on service area, discharge, or user-defined
counts.
Throughout the program and documentation, the term Unit Sanitary (Dry Weather) Load(s)
may be abbreviated as Unit Dry Load(s).

12.9.1

Population-Based Unit Sanitary (Dry Weather) Load Properties
The most common way of specifying sanitary loads to a sewer system is to make them proportional to the
contributing population. Population-based unit sanitary loads define loads as a function of adjusted
contributing population. You can select the population loading units that will be used and the unit load per
population unit. For example, the unit sanitary load, Home (Average), specifies Resident as the population
loading unit, and 280 l/d per Resident as the unit load per population unit.
The population-based unit sanitary load is defined by:
Label - The name of the unit sanitary load as it will appear in choice lists.
Loading Unit Type - Type of the unit sanitary load: population-based, area-based, discharge-based, or
used defined count-based. Loading Unit Type is selected upon creation of a new unit sanitary load, and
therefore this field is not editable.
Loading Unit - The base unit used to define the unit load. Loading Unit Type defines the list of available
loading units, such as resident, capita, guest, or employee.
Unit Load - The amount of flow contributed per loading unit.
Population-based sanitary loads can be peaked using any Extreme Flow Factor Method. Also,
use the Notes tab to enter any information relevant to the unit sanitary load.

12.9.2

Non-Population-Based Unit Sanitary (Dry Weather) Loads
Non-population-based unit sanitary loads can be area-based (function of contributing area), dischargebased (function of direct discharge), or count-based (function of a user-defined count). In addition to
loading units and unit load per specified loading unit, non-population-based unit sanitary loads are defined
by the following properties:
Label - The name of the unit sanitary load as it will appear in choice lists.
Loading Unit Type - Type of the unit sanitary load: population-based, area-based, discharge-based, or
user-defined count-based. Loading Unit Type is selected upon creation of a new unit sanitary load.
Loading Unit - The base unit used to define unit load. Loading Unit Type defines the list of available
loading units.
Unit Load - The amount of flow contributed per loading unit.
Population Equivalent - Count of adjusted population per loading unit. Adjusted population is used with
population-based extreme flow factor methods. For area based loads, this is essentially a population
density, or population per unit area.

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197

Report Adjusted Population - If this option is toggled ON, the adjusted population will be reported with
other populations. If the option is OFF, adjusted population will be used only to calculate Extreme Flow
Factors and will not be reported as part of the total population.
Non-population-based sanitary loads are typically peaked using a discharge-based extreme flow
factor method. If you wish to use a Population-Based Extreme Flow Factor Method with a nonpopulation-based sanitary load, the Population Equivalent must be specified.

12.9.3

Area-Based Unit Sanitary (Dry Weather) Loads
Area-based unit sanitary loads are commonly used to specify industrial loads and steady inflows. Use these
unit sanitary loads whenever your load is specified as a function of contributing area.

12.9.4

Discharge-Based Unit Sanitary (Dry Weather) Loads
Discharge-based unit sanitary loads are used to directly specify loads without specifying them on the basis
of some other count, such as population or area.
There are two general ways to use discharge-based loads:


Specify 1.0 discharge unit (e.g. l/day, gpd, cfs, etc.) as the unit load. Then, when using the load,
specify the total desired load for the loading unit count. For example, you can create a load called Liter
per Day whose loading unit type is Discharge, loading unit is l/day, and unit load is 1.0. When you use
this load at a manhole, a wet well, or a pressure junction, you specify 50.0 as the loading unit count.
This yields a base load of 50 l/day.



Specify total desired load as the unit load. Then, when using the load, only specify 1.0 as the loading
unit count. For example, you can create a load called Industry XYZ whose loading unit type is
Discharge, loading unit is l/day, and unit load is 2000.0. When you use this load at the manhole, wet
well, or pressure junction, you would specify 1.0 as the loading unit count. This yields a base load of
2000 l/day.
In other words, you can specify a unit load of 1.0 in the Unit Sanitary Load Library and determine the
total load at each node through the loading unit count, or you can specify the total load in the Unit
Sanitary Load Library and then have a loading unit count of 1.0.

12.9.5

Count-Based Unit Sanitary (Dry Weather) Loads
Count-based unit sanitary loads should be used for any load that is not area, population, nor dischargebased. These loads allow you to specify any loading unit such as loading per vehicle, machine, or anything
else.
Loading units in user-defined counts are treated only as labels. Conversion between these units
is always 1 to 1.

Notes

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199

Chapter 13
GIS and Database Connections
13.1 Overview
Haestad Methods’ GIS/Database Connection feature provides the modeler with the ability to dynamically
exchange data with a variety of applications. You can establish a "connection" between your hydraulic
model and relational and non-relational database management systems (RDBMS and DBMS),
spreadsheets, and ESRI Shapefiles. Throughout the rest of this chapter, the term "external file" will be used
to generically refer to any one of these types of files. Where information pertains to a specific type of
external file, that type will be used.
The GIS/Database Connection system is extremely powerful. It can be used to update hundreds or
thousands of database records with a few clicks of the mouse. This chapter provides detailed information
on the structure and behavior of the system so that it can be used more effectively.
The purpose of the GIS/Database Connection system is to provide you with a safe and convenient means of
exchanging data with external files. This system has several advantages over simply providing an open file
format for direct manipulation by the end user.
Generality - Open file formats have a specific form that must be adhered to. This restrictiveness is
problematic for both the developer and the end user. Developers are now under additional constraints when
modifying the software. They must be cognizant of the fact that users may depend on this format, and are
therefore less free to modify it. The end user, on the other hand, has no control over this format, and is at
the mercy of the developer. A new version may change the format completely, and all of your existing data
must be converted. In addition, the file format is rarely convenient for an end user since it is typically
chosen for efficient processing by the program. The GIS/Database Connection system allows you to
exchange data between the model and any arbitrarily defined external files. This flexibility allows you to
set up a database or spreadsheet, and it frees the developer to use a file format that is most efficient for the
program.
Data Protection - Open file formats can typically be modified by anyone, often without the knowledge of
the modeler. By providing an interface to exchange data, the model is protected from inadvertent changes.
The modeler is in complete control of when and how the model or external files are updated.
Type Coercion - Quite often the external files do not store the data using the format expected by the
hydraulic model. For example, a database may store the length of a pipe using single precision floating
point numbers, whereas the model works with double precision floating point numbers. When exchanging
data between the model and the external file using the GIS/Database Connection system, the data is coerced
from one type to the other automatically.
Unit Conversion -The quantities used in hydraulic models almost always have some unit associated with
them. For example, pipe lengths are typically expressed in meters or feet. General purpose database and
spreadsheet applications do not support the concept of unitized numbers. A pipe length, for example, is
simply represented as 100.0. Is that 100.0 meters or 100.0 feet? The GIS/Database Connection interface
allows you to specify the database unit so the numbers can be converted from the model unit to the
database unit and vice versa.

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Virtually all model inputs and calculated results can be exchanged through the GIS/Database Connection
system. The system not only supports the update of existing model elements and external file records, but
also the creation and deletion of these elements and records. For example, by performing a Sync In
operation (explained in detail below), an entire hydraulic model can be built from data stored in a
spreadsheet. Likewise, an empty spreadsheet can be completely populated with data from an existing
hydraulic model by performing a Sync Out operation. The spreadsheet can be kept synchronized with the
hydraulic model over the course of a project as new elements are added or deleted, and the input and output
data is modified.
The GIS/Database Connection system has a three-tiered architecture:


Connections



Table or Shapefile Links

• Field Links
The first tier is the Connection. Connections are organized and managed by Connection Managers.
There are two types of Connection Managers: a Database Connection Manager and a Shapefile
Connection Manager. As the names imply, the first manages connections to databases and spreadsheets,
and the second manages connections to ESRI Shapefiles. The Connection Managers are similar, and
provide an interface for adding, editing, deleting, duplicating, and synchronizing Connections.
To exchange data between the model and external files, a Connection must be created and then
synchronized. The two synchronization operations that can be performed on a Connection are Sync In and
Sync Out. Sync In synchronizes the model to the data contained in external files. In this case, the model
acts as a "consumer" of the data, and external files act as the data "provider". Sync Out synchronizes
external files to the data contained in the model. Thus, for Sync Out, the model is the data provider and
external files are the consumers. Exactly what data is exchanged during synchronization depends on how
the Connection is defined. Intuitively, a Connection must specify which files are to be connected to the
model, and what data in each file is to be exchanged.
The second tier is the Table or Shapefile Link. A Database Connection uses these links to gather and store
information. Each Connection can contain one or more Table or Shapefile Links. Each of these links
specifies the type of external file with which to exchange data (implied with Shapefile links), the name of
the file, and, if the file contains multiple tables, which table within the file is of interest.
The third tier of the system is the Field Link. Each Table or Shapefile Link uses one or more Field Links to
specify exactly what data in the external file is going to be exchanged. A Field Link defines the
fundamental mapping between a field in an external file and a field in the model. For example, a field link
may be used to "map" the GRND_FT field of an external database file to the Ground Elevation attribute of
the model.
In summary, a Connection defines a link between the model and external files. Table or Shapefile Links
and Field Links are used to specify files, tables, and fields to be linked. Once a Connection is created, it
can be synchronized in or out. The synchronization action will update models ("in" direction) or the
external files ("out" direction).
The rest of this chapter provides details on the dialogs and windows used to interact with the GIS/Database
Connection system. Although Database Connections and Shapefile Connections are similar in concept,
there are differences in the interfaces and options. Therefore, they will be discussed in separate sections.

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13.2 Database Connections
13.2.1

Database Connection Manager
This manager, accessed by selecting File / Synchronize / Database Connections from the pull-down
menu, helps you track and work with database connections. On the left side of this dialog is a list of the
current database connections.
There are several options available in the Database Connection Manager, including:


Add - Creates a new database connection using the Database Connection Editor.



Edit - Changes the configuration of the currently selected connection. This will open the Database
Connection Editor, where you can rename the connection, change the associated database files, and
perform other changes to the connection configuration.



Duplicate - Creates a connection identical to the selected one. This feature is very helpful when
defining two or more connections with many similar attributes.



Delete - Removes the selected connection from the list.



Synchronize In - Updates the network attributes from the databases defined in the selected
connection.



Synchronize Out - Updates all databases in the connection from the current status of the model.

• Reset - Returns the highlighted standard database import or export connection to default settings.
When synchronizing in, output fields such as hydraulic grade line or computed pipe flow will not be
updated. If an attempt is made to update an output field during a Synchronize In operation, a "Read Only
Warning" will be issued in the status log, indicating which attribute could not be updated.
When synchronizing out, all mapped information will be overwritten in the database files, including input
and output conditions.
If you do not want your input values overwritten upon synchronizing out, simply duplicate the
connection. Then, edit one connection such that it includes only the values you want to
synchronize in, and one that includes only the values you want to synchronize out.
When synchronizing out, be sure that the model element labels are of the same data type as the
database column to which you are mapping. Otherwise, synchronizing out to the database will
yield erroneous results. For example, if you were to synchronize in from a database where your
pipe identifier was numeric, then any changes or additions to the pipes in the model should also
use a numeric-labeling scheme. To assure the consistency in type in this case, select Element
Labeling from the Tools menu and remove the appropriate element prefixes before any changes
are made to the model.
To access the Database Connection Manager, select File / Synchronize / Database Connections. From
this dialog, there are two ways to get to the Database Connection Editor. You can click Add to create a
new connection, or select Edit to change an existing connection.

13.2.2

Standard Database Import/Export
The Database Connection Manager is initialized with four standard database connections for importing
and exporting model data using simple File menu commands. These standard connections are as follows:


[Project Export - SI] - Used for the File / Export / Database command when the global unit system
is set to System International.

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[Project Export - US] - Used for the File / Export / Database command when the global unit system
is set to US Customary.



[Project Import - SI] - Used for the File / Import / Database command when the global unit system
is set to System International.



[Project Import - US] - Used for the File / Import / Database command when the global unit system
is set to US Customary.
The purpose of the standard database connections is to provide a powerful yet easy-to-use method of
exposing the model data to external applications using a standard database format, Microsoft Access
database (.mdb). This method is powerful because it provides you with all the flexibility and functionality
of a user-defined database connection, such as unit conversion and type coercion. It is easy to use because
it is predefined with all of the standard model data, and requires nothing more than a file name to execute.
The standard database connections are almost identical to user-defined database connections with the
following exceptions:


Standard connections cannot be deleted.



The label of a standard database connection cannot be changed.



The target database for a standard database connection is determined at the time it is synchronized.
During a Synchronize In operation, you will be prompted to choose an existing Microsoft Access
Database (.mdb). During a Synchronize Out, you will be prompted for the name of a new Access
database. If an existing filename is chosen, a warning will indicate that the existing file will be
overwritten.



The field names of the external database tables are editable from within the Table Link Editor.



The Database Type on the Table Link Editor cannot be changed.



Standard connections can be reset to their factory default values. To do this, select a standard
connection from the list in the Database Connection Manager, and click the Reset button.
By default, the standard database connections include a table link for each element type, and field links for
all the attributes related to that element type, with some minor exceptions. The default units for the
specified unit system (SI or US) are used for unitized attributes. The Key Label field is designated as the
key field for each of the table links, and it is created as an index for the table during database creation. No
duplicates are allowed.
As noted above, the field links external field names can be edited directly within the Table Link Editor. It
is valid to have more than one internal attribute "mapped" to a single external field name. Although this is
not the case for the standard connections in their factory default state, you can create this condition. Under
this condition, the following behaviors will be observed:


Import (Synchronize In) - All of the attributes will be populated with the value of the database field if
it is a valid value for the specified attributes.



Export (Synchronize Out) - The database field will be populated with the last non-blank attribute
value.
If an existing filename is chosen during export, the existing database file will be overwritten.
Therefore, any custom tables, queries, or forms present in that database will be lost.
Model data that are typically a collection of data (e.g. SewerCAD unit sanitary loads, StormCAD
watershed areas and rational C coefficients, and WaterCAD junction demands) cannot be
written to a single record, and are therefore not exported to the database. However, if these
collections only contain a single item, that single item will be transferred to and from the
database during export and import.

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By default, the Standard Database Export creates Microsoft Office 2000 Access files. These files cannot be
read with Office 97. If you want to use Office 97, you need to use a text editor to edit the HAESTAD.INI
file located in your HAESTAD directory, and replace the line:
ConnectionDatabaseFormat=0
with:
ConnectionDatabaseFormat=3
Basically, a value of 3 results in the program creating an Office 97 Access file, whereas a value of 0 will
have the program generate an Office 2000 Access file.
Use the File / Import / Database menu item to import data using the standard database connections.
Use the File / Export / Database menu item to export data using the standard database connections.
Use the File / Synchronize / Database Connections menu item to view or edit the standard database
connections.

13.2.3

Database Connection Editor
The Database Connection Editor is used for defining the group of table links to be included in the
connection. The Database Connection Editor has tabs for Database Connection and Synchronization
Options.
There are three standard operation buttons at the bottom of the dialog:


OK - Accepts the current condition of the connection, including any changes that have been made.



Cancel - Closes the Database Connection Editor without saving any changes.

• Help - Opens the context-sensitive Help system.
To access the Database Connection Editor, select File / Synchronize / Database Connections from the
pull-down menu. This will open the Database Connection Manager. From this dialog, there are two
ways to get to the Database Connection Editor. You can click Add to create a new connection, or select
Edit to change an existing connection.

Database Connection Tab
The Database Connection tab of the Database Connection Editor provides an interface for the standard
attributes of a connection. It contains the following:


Connection Label - A required unique alphanumeric identification for the connection. This is the label
that appears in the list on the Database Connection Manager dialog.



Table Links - Provide basic information about each table link, such as the referenced database file, the
specific table within the database, and the type of table that is referenced. A table link can be
highlighted from the list, at which point the following commands can be performed using the buttons
on the right side of the dialog:


Add - Adds a new table link. If there are no table links currently defined for this connection,
this will be the only button available.



Edit - Changes the characteristics of the selected table link, such as the referenced file or
table, or the mapping of the table’s field links.



Duplicate - Duplicates the selected table. This command is very helpful when defining two
or more table links with similar attributes.



Delete - Deletes the selected table link from the connection.

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Synchronization Options Tab
The Synchronization Options tab of the Database Connection Editor provides an interface for some of
the behaviors of the connection. These options cannot be accessed until the Table Links are defined, and
are as follows:


Add objects to destination if present in source - If this option is selected, when performing a
Synchronize Out for example, elements that are present in the model but are not found in the database
file will be created in the database. If this is not checked, only the elements that are present in both the
model and the database will be updated.



Prompt before adding object - If this is checked, you will get a dialog notifying you of each
unmapped element in the source, and asking if you would like to create a new element in the
destination. If this is not checked, the additional elements will be automatically created in the database.



Remove objects from destination if missing from source - If this is checked when synchronizing
out, elements that are present in the database but not in the model will be deleted from the database. If
this is not checked, the unmapped elements will be ignored.



Prompt before remove - When this box is checked a dialog will appear notifying you of each
unmapped element in the destination and asking if you would like to remove that element. If the box is
not checked, the additional elements will be automatically removed from the database.
In order to be successfully created from the database, pipe elements must have a Start and Stop
node associated with them. This association can be established by mapping the ‘+ Start Node’
and ‘+ Stop Node’ attributes in the pipe table link, or by the ‘+ In Link’ or ‘+ Out Link’ of a
node table link. Mapping both the pipe table and node table attributes may result in the reading
of redundant data causing the connection to fail.
By default, elements created from a database are located at coordinate (0,0). This behavior can
be overridden by mapping the X and Y or Northing and Easting attributes of the node elements.

Database Table Link Editor
The Table Link Editor is a tool for defining or modifying a table link. This dialog is separated into two
groups, one dealing with the file and table information, and the other dealing with the field links (attribute
mapping).
The general table link information includes:


Database Type - Type of database to which the link will be made. There are many types of external
files that can be linked into the model. Among these are Btrieve, Dbase, Excel, FoxPro, Jet (.mdb
files, such as Access), Lotus, and Paradox, as well as Oracle, Sybase, SQL Server, or any other Open
Database Connectivity (ODBC) compliant database.



Database File - File referenced by the table link. To browse directories and specify a file path, click
the ellipsis (...) button.



Database Table - Once the external file has been selected, it will be scanned for tables (or
worksheets), which will then be available for selection from this field. Only one table can be linked
for each table link, but table links can be easily duplicated and edited from the Database Connection
Editor.



Table Type - Defines the type of data that can be mapped for this particular table link. For example, a
Pipe type of table link means that the available model attributes to be mapped are items such as
material, roughness coefficient, flow rate, and velocity.



Key\Label Field - Key by which the entire database-model mapping is defined. The model references
each element by a unique alphanumeric label, and the database must contain the same labels in one of

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the columns. If the key field for you data type is numeric, you will want to be sure that your model
labels include numbers only. Make sure that there are no duplicate element labels/keys within the data
source.
The Field Links group is a manager for the attribute mapping. The tabular list in this group has three field
columns:


Model (SewerCAD, StormCAD, WaterCAD) - Each item in this column is an attribute in the model
that is being mapped to the database. The list of available attributes depends on the type of the table.
Clicking the button
in the Field Links cell will open the Quick Attribute Selector. This will
allow you select attributes from organized categories to more easily find needed attributes.



Database - Each item in this column is a heading from the database table, which correlates to the item
in the model being mapped.



Unit - This column defines the units of the values in the database. During a synchronization operation,
the values will automatically be converted to the appropriate units to maintain the desired unit systems
in both the model and the database. No conversion on your part is required.
In addition to the standard table operations of Insert, Duplicate, and Delete, the Field Links Manager
offers the following additional operation:


Select - Opens the Select Field Links dialog for an efficient method of selecting the fields of interest
from the available model fields.
To access the Table Links Editor, select File \ Synchronize \ Database Connections from the pull-down
menu. This will open the Database Connection Manager. Click Add to create a new connection, or
select Edit to change an existing connection. From the Database Connection Tab of the Database
Connection Editor, click Add or Edit.

Select Field Links
The Select Field Links dialog provides an easy-to-use interface for populating the Field Links group of
the Table Link Editor or Shapefile Link Editor.
The dialog contains two lists:


Available Items - Model attributes that are available for mapping in the current Table or Shapefile
Link.

• Selected Items - Model attributes that have been selected for mapping.
The following buttons are provided to move items from one list to the other:


[>] - Moves the selected item or items from the Available Items list to the Selected Items list.



[>>] - Moves all items from the Available Items list to the Selected Items list.



[<] - Moves the selected item or items from the Selected Items list to the Available Items list.



[<<] - Moves all items from the Items Selected list to the Available Items list.
The Select Field Links dialog provides functions similar to the Table Setup dialog. Please refer to
Selected Table Columns help for information on topics such as selecting multiple attributes.

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ODBC
About ODBC
ODBC, which stands for Open Database Connectivity, is a standard programming interface developed by
Microsoft for accessing data in relational and non-relational database management systems (DBMS).
Using ODBC, applications such as Haestad Methods’ engineering software can access data stored in many
different PC, minicomputer, and mainframe DBMS, even though each uses a different storage format and
programming interface.
The ODBC architecture conceptually consists of three parts:
1.

The application program - The Haestad Methods product.

2.

The Data Source Administrator Program - Embedded in Microsoft Windows.

3. The low-level drivers for accessing specific databases - Supplied by your database vendor.
Although most computers with Windows will have ODBC present, the exact databases you can interface
via ODBC will depend on the databases and drivers installed on your computer.
ODBC is powerful because it is generic and can access many database systems, including mainframe, GIS,
and legacy systems. However, because ODBC must be general, it is slower, more complex, and more
difficult to use than working directly with a database. When you have the option to work directly with a
database, you will usually find it faster and easier than going through ODBC.
For specific information about ODBC in your environment, see your database vendor’s documentation.
For general information on ODBC, see the online Help for the ODBC Data Source Administrator Program.
To find the Administrator Program, go to the Control Panel of your computer and double-click the ODBC
icon. Choose the Help button on the dialog that appears, and go to the Help Contents.

ODBC Database Type
The first field of the database connection Table Link Editor is the Database Type. The list box displays
the external databases and versions supported by the Database Connection feature. One of the Database
Types you can select is ODBC. This does not refer to a specific database or version. It is actually a link to
the ODBC Data Source Administrator Program running on your computer. This link will provide an
interface between the Haestad Methods’ Database Connection and a specific DBMS and source database
file.

ODBC Database File
If you have selected ODBC as the Database Type, when you click the ellipsis (...) button next to the
Database File field the ODBC Data Source Administrator Program will take over and offer a list of the
ODBC data sources installed on your computer. Depending on how your computer is configured, you may
see database systems or actual database files from which to choose.
You will also see database systems such as Microsoft Jet or Excel that are supported directly via
choices in the Database Type list. In general, the Database Connection feature will work faster
by choosing these database systems directly rather than going through ODBC.
If you choose a data source from the Administrator Program, upon returning to the Table Link Editor you
will see an ODBC "connect string" in the Database File field, rather than a file path. This connect string is
a series of key = value pairs, separated by semicolons. It specifies the database location, security
parameters, and access options needed by the particular ODBC driver you are using. In general, you
should not edit this string in any way as you could introduce an error that would prevent the ODBC driver
from accessing the data source you have selected.

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If you are unable to successfully synchronize to the data source using the default form of the
ODBC string, it is possible that you may need to add some parameters to the string that are
specific to your environment. See your database vendor’s ODBC documentation for details.

Synchronizing Via ODBC
Once you have successfully created and entered the data for a database connection that uses ODBC, the
Synchronize In and Synchronize Out operations perform as they do for any other database format.
However, ODBC databases are accessed with slightly different internal mechanisms, and thus may generate
different error conditions. If a synchronization fails to complete, see the status log for error messages.
Note the project or database object the program was processing when the error occurred. Refer to your
database vendor’s documentation for detailed information on any errors reported.
Using ODBC to access SQL Server databases will result in an error #3197 if the synchronization attempts
to delete a database record. To avoid this error uncheck Remove Objects on the Synchronization
Options tab of the Database Connection Editor.

ODBC Database Tables and Fields
There are many complexities in successfully accessing ODBC databases. You will know if there are
problems on your machine because the Database Table or other database-related fields will not have any
entries in the associated drop-down lists.
If this happens, confirm that ODBC is installed and operating correctly on your computer. Double-check
that the ODBC data source you are trying to reference actually exists and is accessible by other programs in
your environment. Check the HAESTAD.LOG file for error messages pertaining to ODBC. If none of
these steps helps you correct the problem, please call Haestad Methods' Technical Support.
Given the diversity of ODBC database drivers and the difficulty of reproducing your networked computing
environment, we cannot guarantee that the Database Connection feature will function with all ODBC
databases. However, we will try to determine the source of your problem and offer a fix or workaround if
possible.
If you edit the connect string manually, you will need to re-enter the dependent fields such as Database
Table and Field Links.

13.2.5

Sharing Database Connections between Projects
Sharing Database Connections between Some Projects, but Not All Projects
When SewerCAD works with database connections, it is using a file with an ".HDC" extension, which
stores the information regarding database files, table links, and field mapping.
Upon opening a SewerCAD project file (.SWR), SewerCAD first looks for a file in the same directory and
with the same filename as the ".SWR" file but with the ".HDC" extension. If it finds this file, it uses the
database connectivity information contained therein. If it does not find this file, then it defaults to a file in
the installed SewerCAD directory called "SWRC.HDC".
Sharing Database Connections between Projects
If you are working on a local drive, and you have several project files all of which reference common
connection information, let your project files automatically default to the "SWRC.HDC" file. Any
connectivity changes that you work on in one project will be automatically reflected when you open any
other project.
If there are several people working on different projects on different computers but still wishing to have
common connectivity information, the appropriate ".HDC" file can be copied (and renamed if necessary) to
the individuals’ local drives.

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Preventing Database Connectivity Sharing between Projects
There are times when shared connectivity can be more cumbersome than helpful (such as when there are a
lot of projects, each with different database connectivity). At these times, it is more useful to have the
connectivity associated with one specific project, rather than with all projects. To do this, simply copy the
"SWRC.HDC" file from the installed SewerCAD directory to the same location as your project file, and
rename "SWRC.HDC" to have the same name as your ".SWR" file.
For example, if your SewerCAD project file is PROJECT1.SWR, rename SWRC.HDC to
PROJECT1.HDC. The connections in PROJECT1.SWR can then be modified without the effects being
reflected in any other projects, and without seeing the effects of changes made to other projects.

13.2.6

Database Connection Example
To connect your model to an external file, take the following steps:
From the File menu, select Synchronize / Database Connections to open the Database Connection Manager.
Click Add.
1.

In the Database Connection Editor, type a label for your Connection.

2.

Click Add to create a new table link. This will take you to the Table Link Editor.

3.

Select the type of file to which you would like to link, and then click the ellipsis (…) button to
browse for and select your database file.

4.

Choose the table to which you would like to link, and the type of table.

5.

Choose the Key/Label Field to define the column in the database that contains the labels of the
elements to be synchronized.

6.

Define as many field links as you want by selecting the model attribute and the associated
database column and unit.

7.

Click OK to exit the Table Link Editor.

8.

Click OK again to exit the Database Connection Editor.

9.

You should be back at the Database Connection Manager. You can leave this dialog and return
to the model, or you can choose to Synchronize In to the model from the database, or
Synchronize Out to the database from the model. Click OK to save changes and exit back to the
model. Click Cancel not to save changes and exit back to the model.

13.3 Shapefile Connections
13.3.1

Shapefile Connection Manager
This manager is identical to the Database Connection Manager, except that it helps you to track and work
with Shapefile connections rather than database connections. Only a brief description of each dialog
control is presented here. Please refer to the Database Connection Manager topic for a more detailed
explanation.


Add - Creates a new Shapefile connection. This will open the Shapefile Connection Wizard.



Edit - Changes the configuration of the currently selected connection. This will open the Shapefile
Connection Editor.



Duplicate - Duplicates the selected connection.



Delete - Deletes the selected connection from the list.

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Synchronize In - Updates the network attributes from the Shapefiles linked to the selected connection.



Synchronize Out - Updates all Shapefiles within the connection from the current status of the model.
See the Overview at the beginning of this chapter for a general discussion of Shapefile
Connections.

To open the Shapefile Connection Manager, select the File \ Synchronize \ Shapefile Connections menu
item. If there are no existing Shapefile Connections you will be prompted to create a new Shapefile.
Click No if you wish to continue on to the Shapefile Connection Manager.

Shapefile Connection Wizard
The Shapefile Connection Wizard provides an easy-to-use interface for defining a new Shapefile
Connection. It is similar to the Shapefile Import Wizard, but has a few additional steps. The major steps
in the wizard are as follows:


Label - Enters an alphanumeric label to uniquely identify the Shapefile Connection.



Select Element Types - Chooses the types of network elements you wish to connect to Shapefiles.



Shapefile Synchronization Options - Specifies the spatial data unit, and configures other options.



Import Shapefile Link Editor - Chooses the Shapefile to which you want to connect and specifies the
details of the link.



Synchronize Now - Choose whether you want to synchronize the Shapefile Connection when finished
with the wizard. You can choose to synchronize in either direction.

Shapefile Connection Label
The Shapefile Connection Label window allows you to enter a unique alphanumeric label for your
Shapefile Connection. This window is presented in the Import and Export Shapefile Connection
Wizards, as well as the Shapefile Connection Wizard.
Synchronize Now?
The last step in the Shapefile Connection Wizard, the Synchronize Now? Window, allows you to specify
whether you wish to synchronize the Shapefile Connection immediately after editing it in the wizard. The
following options are available:

13.3.2



Synchronize Shapefile Connection - Check this box if you wish to synchronize the connection
immediately upon clicking the Finished button. By default this box is checked. If you uncheck it, you
will return to the Shapefile Connection Manager after clicking the Finished button.



In - Select this radio button if you wish to synchronize the connection in to the model. This will
update the model data from the Shapefiles linked to the connection.



Out - Select this radio button if you wish to synchronize the connection out to the Shapefiles linked to
the connection. This will update the Shapefiles from the model.

Shapefile Connection Editor
The Shapefile Connection Editor is similar to the Database Connection Editor. It offers the tabs for
Shapefile Connection and Synchronization Options.
To use the Shapefile Connection Editor, do the following:
1.

Select Synchronize / Shapefile Connections from the File menu.

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2.

If you do not currently have any Shapefile connections defined, you will be prompted to indicate if
you wish to create one now. If you answer Yes, you will be automatically taken to the Shapefile
Connection Wizard.

3.

If there are connections already defined, or if you answer No to the prompt to create one now, you
will be taken to the Shapefile Connection Manager. Select Edit to open the Shapefile
Connection Editor.

Shapefile Connection
The Shapefile Connection tab of the Shapefile Connection Editor is similar to the Database Connection
tab of the Database Connection Editor. It contains the following:

13.3.3



Connection Label - A unique alphanumeric identification for the connection. This is the label that
appears in the list on the Shapefile Connection Manager dialog.



Table Links - List that provides basic information about each Shapefile link, such as the referenced
Shapefile, the feature type of the Shapefile, and the type of element which is referenced. As with the
other managers, a Shapefile link can be highlighted from the list, at which point the following
commands can be performed using the buttons on the right side of the dialog:


Add - Defines a new Shapefile link. If there are no table links currently defined for this
connection, this will be the only button available. Clicking this button invokes the Shapefile
Link Wizard.



Edit - Changes the characteristics of the selected Shapefile link, such as the referenced file or
the mapping of the Shapefile’s field links. Clicking this button also invokes the Shapefile
Link Wizard.



Duplicate - Creates an identical Shapefile link to the selected one. This is very helpful when
defining two or more Shapefile links with similar attributes.



Delete - Removes the selected Shapefile link from the connection.

Shapefile Link Wizard
The Shapefile Link Wizard is used when adding new Shapefile Links to a Shapefile Connection, or when
editing the existing links of a Shapefile Connection. The first step of the wizard is bypassed when editing
an existing link. The basic steps of the wizard are as follows:


Select Element Type - Similar to the Select Element Types window for importing Shapefiles, except
that radio buttons are used rather than check boxes. This is because a Shapefile Connection represents
a single element type.



Import Shapefile - Choose the Shapefile to which you would like to connect, and the Key/Label
Field to specify the column in the Shapefile that contains the matching element labels in the network.
Define as many field links as necessary. For each link, specify the model attribute, the associated
Shapefile column, and the Unit in which the Shapefile attribute is stored.

• Shapefile Link Summary - Quick review of the details specified in the wizard.
As with all wizards, you can move forward or backward through the process to make changes. Click the
Finished button when you are done making changes to the Shapefile Link.

Shapefile Link Summary
The Shapefile Link Summary window provides an opportunity to review the details of the Shapefile Link
before completing the editing process. The following information is provided in the summary window:


Type - Type of element represented by this Shapefile Link.

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13.3.4



Shapefile - Full path and file name of the Shapefile referenced by this Shapefile Link.



Key/Label Field - Shapefile field used to map Shapefile records to their corresponding network
elements in the model.



Attributes Mapped - Number of Field Links mapped in this Shapefile Link.

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Import Shapefile Wizard
The Import Shapefile Wizard will guide you step-by-step through the process of importing ESRI
Shapefiles. These are the basic steps for importing Shapefiles:


Select Element Types - Select the type of network elements you wish to import.



Shapefile Synchronization Options - Specify the spatial data unit and configure other options.



Import Shapefile - Browse to and select the Shapefiles you would like to import, and select the
Key/Label Field to specify the column in the Shapefile that contains the matching element labels in
the network. Define as many field links as necessary. For each link, specify the network attribute, the
associated Shapefile column, and the Unit in which the Shapefile attribute is stored.



Create Shapefile Connection - Select whether you want to establish a Shapefile Connection. The
Shapefile Connection allows you to update the Shapefile with values from your model, or to update
your model from the Shapefile.
While using the wizard, you can move forward or backward through the process to make changes by
clicking the Next and Back buttons. Click the Finished button when you are done making changes to
import Shapefiles.
To access the Import Shapefile Wizard, select File / Import / Shapefile from the pull-down menus.

Select Element Types
The Select Element Types window is used for selecting the types of network elements that are of interest
when importing and exporting Shapefiles, or when creating a Shapefile Connection. The window contains
a list of network element types with a check box preceding each type.
To select an element type for Shapefile Import, Export, or Connection, put a check mark in the
corresponding box.

Shapefile Synchronization Options
Several options are available to customize the Shapefile synchronization process. The Shapefile
Synchronization Options are available for editing in the Import Shapefile Wizard or through the
Shapefile Connection Editor.
The first group of options is only available when editing a Shapefile Connection. These options are exactly
the same as their counterparts in Database Synchronization Options, and are as follows:


Prompt before adding object

• Prompt before removing object
Unlike the Database Synchronization Options, the Shapefile Synchronization Options do not allow for
optionally adding or removing elements. When synchronized, Shapefiles and the model will contain
exactly the same number of records for the specified element type. For example, suppose a Shapefile
contains a record for the junction labeled J-1. When this Shapefile is synchronized into the model, the
model will automatically add a junction labeled J-1 if none currently exists. Likewise, if J-1 is removed
from the model and then synchronized out to the Shapefile, the record for J-1 will automatically be
removed from the Shapefile. You have no control over this.

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The rest of the options are available during the Shapefile Import Wizard or through the Shapefile
Connection Editor.
Shapefile Unit - Choose a unit from the available list. This is the unit of the spatial data in the Shapefile.
For example, if the X and Y coordinates of the Shapefile represent feet, choose feet from the list. If they
represent meters, select meters. This unit must be the same for every Shapefile in the Shapefile
Connection. If you wish to import Shapefiles that have different spatial data units, create a separate
connection for each unit.
When Missing Connectivity Data
As noted in the Table Link Editor topic, to create a pipe from an external file it is necessary for a pipe to
have a start node and stop node associated with it. Typically, these "connectivity" associations are created
by synchronizing the ‘+ Start Node’ and ‘+ Stop Node’ attributes of the pipe. Since a Shapefile contains
spatial data, it is also possible to establish these associations based on the location of nodes relative to the
end points of the pipe. The following options allow you to customize this behavior:


Establish By Spatial Data - Check this box to configure the synchronization so that any missing
connectivity data (start node, stop node, or both) for a pipe will be established from the spatial data if
possible.



Tolerance - This value represents the distance to be searched when trying to locate nodes for
establishing connectivity for a pipe. All nodes within the tolerance of a pipe’s end point will be
collected, and the closest node will be selected for connection.



Create Nodes if None Found - Check this box if you would like nodes to be created during the
synchronization when no nodes are found within the specified tolerance of a pipe’s end point. If this
box is not checked, and no nodes are found within the tolerance, the pipe will not be created because it
has insufficient connectivity data.

Import Shapefile Link Editor
The Import Shapefile Link Editor is similar to the Database Table Link Editor. Refer to that topic for
detailed information on the following Shapefile Link parameters:


Shapefile - Location of the file that is being referenced by the Shapefile link. This is identical to the
Database File parameter of the Table Link Editor.



Key/Label Field - Key by which the entire Shapefile/model mapping is defined.



Field Links - Identical to the Field Links group of the Database Table Link Editor.

Create Shapefile Connection
The Create Shapefile Connection window provides an opportunity during a Shapefile Import or Export to
specify that a persistent connection containing the Shapefile Links and Synchronization Options be created.
This connection can be used at a later time to synchronize the model and the Shapefiles. The Create
Shapefile Connection window has the following parameters:


Add Shapefile Connection - Check this box if you wish to add a persistent Shapefile Connection to
the Shapefile Connection Manager. By default, this box is checked.



Label - Specify an alphanumeric label for the connection. This field is only editable when the Add
Shapefile Connection box is checked.
To access the Shapefile Import Wizard, select File / Import / Shapefile from the pull-down menus.

Shapefile Import Example
Follow these steps to import one or more Shapefiles into a new or existing model:
From the File menu, select Import / Shapefile to access the Import Shapefile Wizard.

Chapter 13 – GIS and Database Connections
1.

Choose the element types that you wish to import by selecting one or more of the check boxes in
the list, and then click the Next button.

2.

Configure the options for this import. First, select the unit for the spatial data of the Shapefile.
Then, if appropriate for your situation, click the Establish by Spatial Data check box in the
When Missing Connectivity Data group, and enter a value in the Tolerance field. For more
information regarding these options, refer to the section on Shapefile Synchronization Options.
Click the Next button to proceed to the Shapefile Link Editors.

3.

You will be presented with an Import Shapefile Link Editor for each element type you choose
to import. Perform the following steps for each Import Shapefile Link Editor:
a. Enter the name of the Shapefile you wish to import for the specified element type. Click the
ellipsis (…) button to interactively browse for and select your Shapefile.

4.

13.3.5

213

b.

Choose the Key/Label field to define the column in the Shapefile that maps to the element
labels in the model.

c.

Define as many field links as necessary by selecting the model attribute and the associated
Shapefile column and unit. Use the Select button for making the selection process more
efficient. Click the Next button.

Click the Add Shapefile Connection check box if you wish to create a persistent link between
the Shapefile(s) you are importing and the model. If you choose to create a Shapefile
Connection, enter an alphanumeric label to identify the connection. Click the Finished button to
import the Shapefiles.

Export Shapefile Wizard
This program has the capability of exporting network elements in the ESRI Shapefile Format. The ESRI
Shapefile is actually three files that together define the spatial and non-spatial attributes of a map feature.
In the case of Haestad Methods hydraulic models, map features are network elements (e.g. pipes,
junctions). Exporting Shapefiles creates brand new files. If you are exporting a Shapefile to a directory
that already contains a Shapefile of the same name, the existing Shapefile will be completely overwritten.
If you wish to update the Shapefile rather than overwriting it, use the Shapefile Connection feature.
The major components of the Wizard are as follows:


Select Element Types - Choose the type of network elements you wish to export. Each type of
network element will have its own Shapefile associated with it. This component is identical to the
Import Wizard’s Select Element Types component.



Export Shapefile Link Editor - Enter a name for each Shapefile you wish to create. Each Shapefile
name must be no more than eight characters in length, and should not be duplicated. Define as many
field links as necessary. For each link, specify the network attribute. The Shapefile variable will
default to a preset value, which can be edited.



Create Shapefile Connection - Choose whether you want to establish a Shapefile Connection for this
Shapefile. The Shapefile Connection allows you to update the Shapefile with values from your model,
or to update your model from the Shapefile. This component is identical to the Import Wizard’s
Create Shapefile Connection component.
While using the Wizard, you can move forward or backward through the process by clicking the Next and
Back buttons. When you are finished defining it, click the Finished button to create the Shapefile.
To export a specific network element type as a Shapefile, choose File / Export / Shapefile from the pulldown menus. This opens the Export Shapefile Wizard.

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Export Shapefile Link Editor
The Export Shapefile Link Editor is similar to the Database Table Link Editor, with the following
differences:


Shapefile - The name and location for the file that is being exported. The Shapefile name is limited to
eight characters.
The Field Links group is used to specify the attributes and Shapefile column headings that you wish to
export, as follows:


Model - Each item in this column is an attribute in the model that is being exported to the Shapefile.
The list of available attributes depends on the type of table.



Shapefile - Each item in this column is a column heading in the Shapefile being created, which
correlates to the item in the model being mapped. By default, the headings are set to an all-capitals
abbreviation of the attribute name, with spaces and periods replaced by the underscore character. The
column heading can be changed, but must be less than ten characters long and cannot contain periods.
The spatial data in the Shapefiles being created will be in the current display unit for map
coordinates. For example, if the X and Y or Northing and Easting values in the model are
displayed in meters at the time of the export, then the spatial data in the Shapefiles created will
also be in meters.
The values for the exported attributes will be in the current display units for that attribute. For
example, if a junction elevation attribute is displayed in feet at the time of the export, the
Shapefile will contain that value in feet.

Shapefile Export Example
Follow these steps to export one or more Shapefiles from the model:
From the File menu, select Export / Shapefile to access the Export Shapefile Wizard.

13.3.6

1.

Select the element types that you wish to export by selecting one or more of the check boxes in
the list, then click the Next button.

2.

You will be presented with an Export Shapefile Link Editor for each element type you choose
to export. Perform the following steps for each Export Shapefile Link Editor:


Enter the name of the Shapefile you wish to create for the specified element type. Click the
ellipsis (...) button to interactively browse for a directory in which to store the Shapefile.



Define as many field links as necessary by selecting the model attribute and providing a name
for the associated Shapefile column. Use the Select button for making the selection process
more efficient. Click the Next button to continue.



Click the Add Shapefile Connection check box if you wish to create a persistent link
between the Shapefile(s) you are exporting and the model. If you choose to create a Shapefile
Connection, enter an alphanumeric label to identify the connection. Click the Finished button
to export Shapefiles.

Sharing Shapefile Connections between Projects
When SewerCAD works with Shapefile connections, it is using a file with an .HSC extension, which stores
the information regarding the Shapefiles and field mapping for each element type.
When you open a SewerCAD project file (.SWR), SewerCAD first looks for a file in the same directory
and with the same filename but with the .HSC extension. If it finds this file, it uses the Shapefile

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connectivity information contained therein. If it does not find this file, it defaults to a file in the installed
SewerCAD directory called SWRC.HSC.
Sharing Shapefile Connections between Projects
If you are working on a local drive, and you have several project files that all reference common connection
information, let your project files automatically default to the SWRC.HSC file. Any connectivity changes
that you work on in one project will be automatically reflected when you open any other project.
If there are several people working on different projects on different computers, but they still wish to have
common connectivity information, the appropriate .HSC file can be copied (and renamed if necessary) to
the individual local drives.
Preventing Shapefile Connectivity Sharing between Projects
There are times when shared connectivity can be more cumbersome than helpful such as when there are
many projects, each with different Shapefile connectivity. At these times, it is more useful to have the
connectivity associated with one specific project, rather than with all projects. To do this, simply copy the
SWRC.HSC file from the installed SewerCAD directory to the same location as your project file, and
rename it to the same name as your .SWR file.
For example, if your SewerCAD project file is PROJECT1.SWR, rename SWRC.HSC to PROJECT1.HSC.
The connections in PROJECT1.SWR can then be modified without the effects being reflected in any other
projects.

13.3.7

Shapefile Format
An ESRI Shapefile actually consists of three separate files that combine to define the spatial and nonspatial attributes of a map feature. The three required files are as follows:


Main File - A binary file with an extension of .SHP. It contains the spatial attributes associated with
the map features. For example, a polyline record contains a series of points, and a point record
contains X and Y coordinates.



Index File - A binary file with an extension of .SHX. It contains the byte position of each record in
the main file.



Database File - A dBase III file with an extension of .DBF. It contains the non-spatial data associated
with the map features.
All three files must have the same file name with the exception of the extension, and be located in the same
directory.

13.3.8

Shapefile Connection Example
Follow these steps to connect one or more Shapefiles to the model:
1.

From the File menu, select Synchronize / Shapefile Connections.

2.

If you do not have any connections currently defined, you will be asked if you want to create a
new one now. Select Yes. If you already have one or more connections defined, you will go to
the Shapefile Connection Manager. Click Add to access the Shapefile Connection Wizard.

3.

Provide an alphanumeric label to uniquely identify this new connection. Click the Next button.

4.

Choose the element types that you wish to import by clicking one or more of the check boxes in
the list, and click the Next button.

5.

Configure the options for this connection. First select the unit for the spatial data of the
Shapefile. Then, if appropriate for your situation, click the Establish by Spatial Data check box
in the When Missing Connectivity Data group, and enter a value in the Tolerance field. For

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more information regarding these options, refer to the section on Shapefile Synchronization
Options. Click the Next button to proceed to the Shapefile Link Editors.
6.

You will be presented with an Import Shapefile Link Editor for each element type you chose to
import. Perform the following steps for each Import Shapefile Link Editor:


Enter the name of the Shapefile to which you wish to connect for the specified element type.
Click the ellipsis (…) button to interactively browse for and select your Shapefile.



Choose the Key\Label field to define the column in the Shapefile that maps to the element
labels in the model.



Define as many field links as you want by selecting the model attribute and the associated
Shapefile column and unit if appropriate. Use the Select button for making the selection
process more efficient. Click the Next button.

7.

Check the Synchronize Shapefile Connection box if you wish to synchronize the connection
immediately upon clicking the Finished button.

8.

If the Synchronize Shapefile Connection box is checked, choose whether you want to
Synchronize In to the model from a Shapefile, or Synchronize Out to the Shapefile from the
model.

9.

Click the Finished button to synchronize the connection if the Synchronize Shapefile
Connection box is checked, or to return to the Shapefile Connection Manager.

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Chapter 14
Exchanging Data with CAD Software
and Autodesk Civil Design
14.1 AutoCAD Polyline to Pipe Conversion
This feature allows you to quickly construct a network based on the entities contained in an AutoCAD
drawing. Although this feature is called Polyline to Pipe, Line and Block entities can be converted as well.
Polylines and Lines can be converted to pipes and Blocks can be converted to any available node type.
Building a model based on graphical elements can be an error-prone process. This is due to the fact that a
drawing can appear to be correct visually, but may contain problems that are not readily apparent. For
example, what appears to be a single line in a drawing could in fact be made up of many line segments, or
it could be made up of two lines, one directly on top of another.
To help alleviate some of the problems that you may encounter during the import process, a comprehensive
drawing review is also performed. During the conversion process, the network is analyzed and potential
problems are flagged for review. After performing the conversion, the Drawing Review window will
allow you to navigate to and fix any problems that are encountered.
The Polyline to Pipe conversion cannot be undone. Be sure to save your project before you begin.
You can import entities into an existing project. Polylines will automatically be connected to
nodes within the specified Tolerance. You can add nodes to your project prior to performing the
import.
Stand-Alone mode - You should take some time to clean up your AutoCAD drawing prior to
performing the conversion. Look for entities that should not be converted, such as leader lines,
and move them to their own layer. Turn off layers that you do not wish to convert. Do a quick
review of your drawing and correct any potential conversion problems that you may find.
After performing the conversion, we recommend that you use the converted file as a DXF
Background. This will greatly enhance your review process. If you change the entities in your
background drawing to a gray color from within AutoCAD, it will make it easier to distinguish
between foreground elements and background entities.
AutoCAD mode - You can interactively convert individual entities to pipes by using the Layout
Tool.

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SewerCAD only - When importing a drawing that contains both pressure and gravity pipes you
should import your system in two passes. First, import the layer(s) that contain Gravity pipes,
then import the layer(s) that contain Pressure pipes. On the first pass create Manholes at pipe
endpoints, and on the second pass create Pressure Junctions at pipe endpoints. This will ensure
that the correct element will be added where your system transitions from gravity to pressure.
Refer to the related information section on "Converting your drawing in multiple passes" for
more information.

14.1.1

Polyline to Pipe Wizard
The Polyline to Pipe Wizard will guide you step-by-step through the process of converting your entities to
elements.


Step 1 - The import behavior depends on the mode in which you are working:


Stand-Alone - Specify the .DXF file that you would like to import.



AutoCAD - This step is skipped. You will be asked to select the entities to convert before
accessing the Wizard.



Step 2 - Specify the polyline to pipe conversion options.



Step 3 - Specify how T-intersections are to be handled.



Step 4 - Specify how blocks should be converted (for .DXF files that contain blocks).



Step 5 - Configure prototypes.

• Step 6 - Specify the layers to be imported.
To access the Polyline to Pipe Wizard:

14.1.2

Stand-Alone

Select File / Import / Polyline to Pipe from the main menu.

AutoCAD

Select Edit / Change Entities to Pipes from the main menu.

Polyline to Pipe Wizard - Step 1 (Stand-Alone mode only)
This step allows you to specify the .DXF file to be imported.
If you are running in AutoCAD mode, this step will be skipped. AutoCAD mode users will be
asked to select the entities to be converted before accessing the Polyline to Pipe wizard.

14.1.3



DXF Filename - Specify the name of the .DXF file you would like to import. Use the Browse button
to select the file interactively.



DXF Unit - Specify the .DXF conversion unit (the unit that your .DXF file is in). For example, if your
drawing is in SI units, specify meters (m). If your drawing is in architectural units, specify inches (in).

Polyline to Pipe Wizard - Step 2
This step allows you to specify the following Polyline to Pipe conversion options:


Connectivity tolerance - Polylines whose endpoints fall within the specified tolerance will be
connected to the same node. A default tolerance is supplied based on the current scale. This is

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generally a good starting point, but you may wish to increase or decrease this default tolerance
depending on your particular drawing. If you complete the conversion process and find that the
tolerance was not correct (pipes that should be connected were not, or vise versa), you may wish to
repeat the conversion process using a new tolerance.


Specifying which entities to convert - You can optionally convert Polylines, Lines, or both. You
generally want to convert both Polylines and Lines. However, if your drawing is set up so that
Polylines are always used to represent pipes and Lines are used for annotation purposes, you may wish
to convert only Polylines.



Handling missing nodes at polyline endpoints - A pipe can only be created if there is a node at both
endpoints. If a node cannot be found at a polyline endpoint, a node must be added. Otherwise, the
pipe cannot be converted. This option allows you to specify whether a node is created, and, if so, the
default type of element to create.
In general, you will want to create a default node at polyline endpoints. However, if your network already
contains nodes at polyline endpoints, or if your drawing contains blocks at polyline endpoints that are to be
converted to nodes, you may wish to specify that the polyline not be converted. Polylines that cannot be
converted, because one or both end nodes are missing, will be flagged for review at the end of the
conversion process.
If the conversion does not yield the desired results, you can repeat the conversion process using
different settings. Be sure to save your project before performing the conversion.

14.1.4

Polyline to Pipe Wizard - Step 3
This step allows you to specify how T-intersections (pipe split candidates) should be handled.
Nodes that fall within the specified tolerance of a pipe are referred to as pipe-split candidates. There are
two ways to handle these:


Join the pipes at the intersection - The pipe-split candidate will be used to split the intersecting pipe.



Do not join the intersecting pipes - Pipe-split candidates will be flagged for later review using the
Drawing Review window.
The tolerance that you specify in Step 2 will also be used for T-intersection processing.

14.1.5

Polyline to Pipe Wizard - Step 4 (for .DXF files that contain blocks)
If your AutoCAD drawing contains blocks, this step will appear, allowing you to convert AutoCAD blocks,
if desired.
If you would like to convert blocks to nodes, activate the Yes toggle. A table with two columns will
appear, allowing you to map the AutoCAD blocks you would like to convert to any of the available node
element types. The AutoCAD block column provides you with a list of available blocks to convert. The
Element column provides you with a list of available node element types.
For each AutoCAD block you would like to convert, specify the type of node element you would like to
create.
When you select an AutoCAD block, the preview pane will display the graphical representation
of that block. This step will be skipped if there are no AutoCAD Blocks in your drawing.

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Polyline to Pipe Wizard - Step 5
Before performing the conversion, you may wish to configure your prototypes with default data. During
the conversion process, elements will be created using the specified defaults.
Click a button to configure the defaults for the associated element.

14.1.7

Polyline to Pipe Wizard - Step 6
Specify the layers that contain the entities you would like to convert. Use the Preview Drawing button to
preview the elements on the selected layers. This step can be used in conjunction with the Prototype step to
allow you to convert your drawing in multiple passes.
It is recommended that you process your drawing prior to performing the import. If your
drawing contains layers that you do not wish to import, turn them off from within AutoCAD and
elements on those layers will be ignored during the import process.

14.1.8

Drawing Preview
Use the Preview Drawing button to view the elements in the .DFX file that will be converted.
Next to the Preview Drawing button is a checkbox labeled Only include elements that will be converted.
Turn the toggle on to preview the entities that will be converted. The entities to be converted are based on
the settings you specified in the Polyline to Pipe Wizard, such as type of line entities, blocks, and layers to
be converted.
Turn the toggle off to preview all entities.

14.1.9

Polyline Conversion Problem Dialog
This feature is present in Stand-Alone mode only. This dialog displays the reason that a polyline was not
converted after running the Polyline to Pipe Wizard.

14.1.10

Converting your Drawing in Multiple Passes
Depending on how your drawing layers are set up, you may be able to save yourself a considerable amount
of data entry time by converting your drawing in multiple passes.
For example, if your 12-inch pipes are located on a "12InchPipes" layer, 18-inch pipes are on a
"18InchPipes" layer, etc., you can import layers one at a time. Just set up your prototypes prior to
importing that layer.
To assist you in this process, your conversion settings will be retained between imports. Therefore, on
subsequent passes you will simply need to revise your prototypes and specify the next layer to be imported.
This same technique can be used when importing blocks.

14.2 Land Development Desktop - Civil Design Connection
14.2.1

Land Development Desktop Import Wizard
This import procedure allows you to construct a model based on your Land Development Desktop project
data. The Import Wizard will guide you step-by-step through the process of importing data from the Civil
Design module of AutoCAD’s Land Development Desktop.

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Following are the basic steps for importing a Land Development Desktop file containing the pipe data:


File Import Settings - Select the pipeworks.mdb file to import, the unit system in which it is stored,
and the connectivity tolerance.



Runs to Import - Pick the runs that you would like to import from the list of available runs in your
Land Development Desktop project file.



Import Structure Mappings - Specify the mapping between Land Development Desktop structure
names and this application's node types.
You can import a Land Development Desktop data file into an existing project to add new pipes
and structures.

14.2.2

File Import Settings
File Name - Enter the path and name of the file to import, or use the Browse button to select it
interactively. The Civil Design data is stored in a file named pipeworks.mdb located in the pipewks
directory of your Land Development Desktop project directory. For example, if your project is named
"myproject", your data may be stored in C:\Land Projects\myproject\pipewks\pipeworks.mdb.
Connectivity Tolerance - Runs whose end nodes fall within the specified tolerance will be connected to
the same node. A default tolerance is supplied; you may wish to increase or decrease this tolerance
depending on your particular project. If you complete the import process and find that the tolerance was
not appropriate (pipes that should be connected are not, or vice versa), you may wish to repeat the
conversion process using a new tolerance.
Land Development Desktop Unit System - Specify whether the Land Development Desktop project you
wish to import is in the SI or US Customary unit system. The imported data will automatically be
converted to your current project unit system.

14.2.3

Runs to Import
Land Development Desktop maintains network connectivity based on runs. Runs consist of reaches, and
reaches consist of an upstream node and a downstream pipe. A list of all runs present in your Land
Development Desktop file will be displayed. Toggle the check boxes to specify the runs you would like to
import.
Remember that you can always import more runs into your project later.

14.2.4

Import Structure Mappings
A list of the structure labels in your Land Development Desktop file will be displayed. For each structure
label, specify the type of node element that you would like to create.

14.2.5

Land Development Desktop Export Wizard
The Land Development Desktop - Civil Design Export Wizard will guide you step-by-step through the
process of exporting part (or all) of your network to a database file. That database file can then be imported
into your Land Development Desktop project (using the Civil Design module).
Following are the basic steps for exporting data to a Land Development Desktop file:


File Export Settings - Select the name of the database file to which you would like to export your
data, and the unit system in which your Land Development Desktop data is stored.



Runs to Export - Specify runs containing the elements you would like to export.

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Export Structure Mappings - Specify the mapping between this application's node types and your
Land Development Desktop Structure names.
After exporting your data, you can use the Land Development Desktop to import that data into your Civil
Design project. From within the Land Development Desktop, use the Pipes / Import-Export Run /
Import DB menu item to import the desired runs into your Land Development Desktop project. Use the
Conceptual Plan / Import Run command from the Pipes main menu to display each run in a plan view.
Then use the Land Development Desktop functions to generate Plan and Profile sheets as well as
construction drawings.
Only Gravity Elements can be exported.

By default, the Land Development Desktop Export Wizard creates an Office 97 Access file. If you want to
create an Office 2000 Access file, then you need to edit (with a text editor) the HAESTAD.INI file located
in your HAESTAD directory and replace the line:
PipeworksDatabaseFormat=3
With:
PipeworksDatabaseFormat=0
Basically a value of 3 results in the program creating an Office 97 Access file (Jet versions), whereas a
value of 0 will have the program generate the default Office 2000 Access file.

14.2.6

File Export Settings
File Name - Enter the name of the database file to which you would like to export your data, or use the
Browse button to interactively specify the file name.
Land Development Desktop Unit System - Specify whether you want to export data to the Land
Development Desktop in the SI unit system, or in the US customary unit system.

14.2.7

Runs to Export
Land Development Desktop maintains network connectivity based on runs. Runs consist of reaches, and
reaches consist of an upstream and a downstream node. This export command allows you to specify the
runs to be exported. You can either specify the runs interactively, or you can automatically generate a list
of runs to represent the entire network, using the following commands:


Add Runs



Edit Runs



Delete Runs



Initialize Run List
Only gravity elements can be exported.

14.2.8

Add/Edit Pipe Run
Specify the description (or label) for the pipe run, and specify the upstream and downstream nodes that
define that run.

Chapter 14 – Exchanging Data with CAD and Autodesk Civil Design

14.2.9

223

Delete Runs
Removes the selected run from the list of runs to export.

14.2.10

Initialize Run List
Use this option to automatically generate a list of runs to represent your entire network. When you click
the Initialize button, the Element Labeling dialog will appear, allowing you to customize the automatic
run label generation.
After building the run list, modify the default runs using the Add, Edit and Delete buttons.

14.2.11

Automatic Element Labeling
The Element Labeling dialog is used to specify the format of the numbering automatically generated by
the runs using the Initialize button.
Next - Integer you want to use as the starting value for the ID number portion of the run label.
Increment - Integer that you want to be added to the current ID number to build the next run label.
Prefix - Letters or numbers that you want to appear in front of the ID number for the run labels.
Digits - Total number of digits you want the ID number to have.
Suffix - Letters or numbers that you want to appear after the ID number for the run labels.
Preview - An example of what the label will look like, based on the information you have entered in the
fields described above.

14.2.12

Export Structure Mapping
A list of all node types to be exported will be displayed. For each node type, select the Structure label you
want to export to the Land Development Desktop database file. The labels should correspond to those you
are using in your Land Development Desktop Structure Library Editor.

14.3 Import/Export of DXF Files
14.3.1

Import a DXF from AutoCAD or MicroStation
To import background graphics in Stand-Alone mode from another drafting program, you must first export
a .DXF file from your CAD program. This step is usually as simple as selecting an item from a pull-down
menu in that program, such as File\Export\As DXF, or similar command. Once the .DXF file has been
created, it can be imported into this program as follows:

14.3.2

1.

Select the File\Import\DXF Background command from the pull-down menu to access the Import DXF
File dialog.

2.

Select the .DXF file you wish to import, and click the Open button.

Exporting a DXF file
To export the drawing plan view, select File / Export / DXF file from the pull-down menu.
You will be able to redefine all elements, except pipes, as blocks in AutoCAD. Pipes will be
exported as polylines, so you will be able to set their line weight in AutoCAD.

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Chapter 14 – Exchanging Data with CAD and Autodesk Civil Design

Redefining SewerCAD Blocks in AutoCAD
When exporting a .DXF file from SewerCAD, pipes will be exported as POLYLINE entities allowing you
to change the line weights in AutoCAD. Nodes will be exported as BLOCK entities named after the
element, such as MANHOLE, PUMP, WETWELL, and OUTLET. This allows you to redefine them in
AutoCAD.
If you would like to change the appearance of these blocks in your AutoCAD drawing, you can redefine
them by performing the following steps:
1.

Start AutoCAD and create separate drawing files named MANHOLE.DWG, PUMP.DWG,
WETWELL.DWG, OUTLET.DWG, etc. Save these drawings in your AutoCAD directory.

2.

Open the existing drawing that contains the SewerCAD blocks.

3.

At the AutoCAD command prompt, type MINSERT and press Enter.

4.

At the "Block Name:" prompt, type MANHOLE=C:MANHOLE.DWG and press Enter.

5.

You may be prompted to verify that you want to redefine the block. Answer "Yes."

6.

At this point, the block has been redefined and you can cancel this command.

7. Repeat these steps for PUMP, WETWELL, OUTLET, etc.
Refer to your AutoCAD documentation for more information on Redefining Blocks.

14.3.4

Advanced DXF Import Techniques
If you would like to import a SewerCAD .DXF file into an existing AutoCAD drawing file, you will have
to perform a couple of preliminary steps.
1.

In your existing drawing at the AutoCAD command prompt, type (regapp "SWRC") and press
Enter. This will register the SewerCAD application id, so be sure to include the parenthesis.

2. Define blocks named MANHOLE, PUMP, WETWELL, OUTLET, etc.
You are now ready to import a SewerCAD .DXF file into your existing AutoCAD drawing.
To save time, you can perform the above steps in a new AutoCAD drawing file and save it with the name
SewerCAD.DWG. Now, instead of performing the above steps, simply insert this new drawing into your
existing drawing file immediately before importing a SewerCAD .DXF file.
Refer to your AutoCAD documentation for more information on importing .DXF files.

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Chapter 15
Additional Features of the AutoCAD
Version
15.1 Overview
SewerCAD features optional support for AutoCAD integration. You can determine if you have purchased
AutoCAD functionality for SewerCAD by using the Help / About SewerCAD menu option. Click the
Registration button to view the feature options that have been purchased with your application license. If
AutoCAD support is enabled, you will be able to run your SewerCAD application in both AutoCAD and
Stand-Alone mode.
The AutoCAD functionality has been implemented to be essentially identical to that offered with the StandAlone product. Once you obtain familiarity with the Stand-Alone mode, you will encounter few difficulties
utilizing the product in AutoCAD mode.
In AutoCAD mode, you will have access to the full range of functionality available in the AutoCAD design
and drafting environment. The standard environment is extended and enhanced by an AutoCAD
ObjectARX SewerCAD client layer that allows you to create, view, and edit the native SewerCAD network
model while in AutoCAD.
Some of the advantages of working in AutoCAD mode include:


Layout sanitary sewer pipelines and structures in fully scaled mode in the same design and drafting
environment that you use to develop your engineering plans. You will have access to any other third
party applications that you currently use, along with any custom LISP, ARX, or VBA applications that
you have developed.



Use native AutoCAD insertion snaps to precisely position SewerCAD elements with respect to other
entities in the AutoCAD drawing.



Use native AutoCAD commands such as ERASE, MOVE, and ROTATE on SewerCAD model entities
with automatic update and synchronization with the model database.



Output profiles and schematics to your AutoCAD drawing.



Control destination layers for model elements and associated label text and annotation, giving you
control over styles, linetypes, and visibility of model elements.

15.2 SewerCAD Custom AutoCAD Entities (AutoCAD Mode)
This feature is only available in the AutoCAD mode of SewerCAD. The primary AutoCAD-based
SewerCAD element entities - gravity pipes, pressure pipes, manholes, junction chambers, wet wells,
pressure junctions and outlets - are all implemented using ObjectARX custom objects. Thus, they are
vested with a specialized "model awareness," which ensures that any editing actions that you make will
result in an appropriate update of the model database.

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This means that you can perform standard AutoCAD commands as you normally would, and the model
database will be updated automatically to reflect these changes.
This also means that the model will enforce the integrity of the network topological state. So, if you delete
a nodal element such as a manhole, its connecting pipes will also be deleted.
Using ObjectARX enables the implementation of highly specialized editing actions that are not available
with standard AutoCAD entities. Two examples of this specialized behavior are element morphs, which
change a node from one element type to another, and pipe splits. Again, these modifications will trigger an
automatic update of the model network topology and associated element properties.
Using ObjectARX technology ensures that the database will be adjusted and maintained during Undo and
Redo transactions.
A custom model element has certain native text entities associated with it for displaying label and
annotated property values. These associated label and annotation entities may be edited separately from the
model element itself. However, most drawing edits made directly to a model element will also be applied
to its associated label and annotation entities. Thus, if you drag an element to a new location, the
annotation and label locations will update as well.

15.3 AutoCAD Environment
15.3.1

AutoCAD Mode Graphical Layout
In AutoCAD mode, Haestad Methods' products provide a set of extended options and functionality beyond
those available in Stand-Alone mode. This additional functionality provides enhanced user control over
general application settings and options and extends the command set, giving the user control over the
display of model elements within AutoCAD.
Key differences between AutoCAD and Stand-Alone mode include:

15.3.2



Element editing functionality has been extended by adding the Scale Elements and Rotate Labels
commands, accessible under the Edit / Modify Elements pull-down menu, and the Change Width
command under the Edit / Pressure Pipes pull-down menu.



You can control the appearance and destination of all model elements using the Element Properties
command under the Tools pull-down menu. For example, you can assign a specific layer for all
outlets, as well as assign the label and annotation text style to be applied.



Though right-click context menus are now standard with AutoCAD 2000 and 2000i, a Right-Click
Context Menu Option has been added to provide optional conformity with the Stand-Alone mode of
operation in AutoCAD R14.

Toolbars
In AutoCAD mode, the following toolbars are available:


Command Tools - Enables the Command Toolbar for quick access to the main commands, including
computations, tables, graphic reports, Quick View, and direct access to the Haestad Methods Web Site.



Layout Tools - Enables the Layout Toolbar for access to the Tool Palette.



Analysis Toolbar - Enables the Analysis Toolbar to control the current scenario and provide quick
access to the Scenario Manager and Cost Manager, as well as time and animation controls.
To toggle the display of the Haestad Methods command and layout toolbars, select View / Toolbars from
the pull-down menu.

Chapter 15 – Additional Features of the AutoCAD Version

15.3.3

227

Drawing Setup
When working in the AutoCAD mode, you may work with Haestad Methods’ products in many different
AutoCAD scales and settings. However, Haestad Methods’ product elements can only be created and
edited in model space.

15.3.4

Symbol Visibility
This is only available in the AutoCAD mode of SewerCAD. You can control display of element labels
using the Show Labels checkbox, found by selecting Tools / Options from the pull-down menu and
choosing the Drawing tab.
The following commands allow you to customize the drawing by turning the visibility of flow arrows
and/or labels on or off without accessing the Options dialog.


To turn on the element labels, type: SWRCLABELSON



To turn them off, type: SWRCLABELSOFF
In AutoCAD, it is possible to delete element label text using the ERASE command. You should
not use ERASE to control visibility of labels. Instead, the command above. If you desire to
control the visibility of a selected group of element labels, you should move them to another layer
that can be frozen or turned off.
See Rebuild Figure Labels for more information on restoring labels that have been erased using
the native AutoCAD command.

15.3.5

Rebuild Figure Labels
This is only available in the AutoCAD mode of SewerCAD. It is possible to delete element label text
entities. Element labels which have been erased can be selectively undeleted using the command
SWRCREBUILDLABELS.

15.4 AutoCAD Project Files
When using SewerCAD in AutoCAD mode, it is important to remember that two files (file extensions
shown in parentheses) fundamentally define a SewerCAD model project:


Drawing File (.DWG) - The AutoCAD drawing file contains the custom entities that define the model,
in addition to the planimetric base drawing information that serves as the model background.



Model File (.SWR) - The native SewerCAD model database file contains all the element properties
along with other important model data. SewerCAD .SWR files can be loaded and run using the StandAlone mode. These files may be copied and sent to other SewerCAD users who are interested in
extending or running your project. This is the most important file for the SewerCAD model.
The two files will have the same base name. It is important to understand that simply archiving
the drawing file is not sufficient to reproduce the model. You must also preserve the associated
.SWR file.

Since the .SWR file can be run and modified separately from the .DWG file using Stand-Alone mode, it is
quite possible for the two files to get out of sync. Should you ever modify the model in Stand-Alone mode
and then later load the AutoCAD .DWG file, the SewerCAD program will compare file dates and
automatically invoke its built-in AutoCAD Synchronization routine.

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Chapter 15 – Additional Features of the AutoCAD Version

Drawing Synchronization
Whenever you open a SewerCAD-based drawing file in AutoCAD, the SewerCAD model server will start.
The first thing that the application will do is load the associated SewerCAD database (.SWR) file. If the
time stamps of the drawing and database files are different, SewerCAD will automatically invoke its
synchronization check. This protects against corruption that might otherwise occur from separately editing
the SewerCAD database file in Stand-Alone mode or editing proxy elements at an AutoCAD station where
the SewerCAD application is not loaded.
The synchronization check will occur in two stages:
1.

During the first stage of the check, SewerCAD will review all the drawing model elements and
compare their state with that held in the server model. Any differences it discovers during this
check will be listed. SewerCAD enforces network topological consistency between the server and
the drawing state. If model elements have been deleted or added in the .SWR file during a StandAlone session, or if proxy elements have been deleted, the application will force the drawing to
be consistent with the native database by restoring or removing any missing or excess drawing
custom entities.

2.

After network topology has been synchronized, the application will compare other model and
drawing state such as location, labels, and flow directions. Again, it will list any differences
between the drawing client and server data, but a message box will pop up giving you an
opportunity to indicate which state, drawing or model server, should be adopted during the
second stage of synchronization.
You can run the synchronization check at any time using the command SWRCSYNCSERVER.

15.4.2

Saving the Drawing as Drawing*.dwg
AutoCAD uses Drawing*.dwg as its default drawing name. Saving your drawing as the default AutoCAD
drawing name (for instance Drawing1.dwg) should be avoided, as it makes overwriting model data very
likely. When you first start AutoCAD, the new empty drawing is titled Drawing*.dwg, regardless of
whether one exists in the default directory. Since Haestad Methods’ modeling products create model
databases associated with the AutoCAD drawing, the use of Drawing*.dwg as the saved name puts you at
risk of getting the AutoCAD drawing and Haestad Methods modeling files out of sync.
If this situation is forced to occur (save on quit for example), simply restart AutoCAD, use the
Open command to open the Drawing*.dwg file from its saved location, and use the Save As
command to save the drawing and model data to a different name.

15.5 Element Properties
When working in the AutoCAD mode, this feature will display a tabbed dialog with tables containing
different model element types and their associated properties, along with the properties of the element’s
layer, label, and annotation. To modify an attribute, double-click each associated grid cell. Setting changes
made in this dialog will be used for any newly created elements. Property changes will be performed on all
elements of the given type. If the Apply to Existing Object box is checked, modifications made in this
dialog are performed on a global basis. To restrict global changes to a certain layer for a particular element
type, use the "*current*" option setting for the attribute of interest.
To change the layer, label, or annotation of an element, select Tools / Element Properties from the pulldown menu.

Chapter 15 – Additional Features of the AutoCAD Version

15.5.1

229

Select Layer
When running in AutoCAD mode, this dialog appears when you double-click the layer name ("*current*"
by default) in the Layer column of the Element Properties dialog. This is accessed by selecting Tools /
Element Properties from the pull-down menu. It displays a list of the available layers and their properties
from the current AutoCAD drawing. Click the appropriate field to select a layer. The "*current*" option
will use whatever layer is set to current in your AutoCAD drawing.

15.5.2

Select Text Style
When running in AutoCAD mode, this dialog appears when you double-click the text style name
("*current*" by default) in the Text Style column of the Labels and Annotation tabs of the Element
Properties dialog. This is accessed by selecting Tools / Element Properties from the pull-down menu. It
displays a list of the available text styles and their properties from the current AutoCAD drawing. Click the
appropriate field to select a text style. The "*current*" option will use whatever text style is set to current
in your AutoCAD drawing.

15.6 Working with Elements
15.6.1

Edit Element
In AutoCAD mode, this menu selection will open an element editor for any specific element. Select Edit /
Edit Element, then select an element. This command is also available by choosing the Select tool, then
clicking an element in the drawing pane.
The Edit Element command works with the current selection to allow you to generate filtered reports.
Refer to Selecting Elements (AutoCAD Mode) for more information on working with selections.

15.6.2

Edit Elements
In AutoCAD mode, this menu command is used to open a spreadsheet FlexTable editor or a selection of
one or more network figures. You are prompted to select figures on which to build a table.

15.6.3

Deleting Elements
In AutoCAD mode, this command removes all elements in the current selection. Refer to Selecting
Elements (AutoCAD Mode) for more information on working with selections.

15.6.4

Modifying Elements
Modify Elements
In AutoCAD mode, these commands are selected from the Edit pull-down menu. They are used for scaling
and rotating model entities.

Scale Elements
In AutoCAD mode, this menu selection resizes an element based upon a scale factor. After choosing this
command, select an element or group of elements, and enter the scale factor to be applied.
To access the Scale Elements command, select Modify Elements from the Edit pull-down menu.

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Chapter 15 – Additional Features of the AutoCAD Version

Rotate Labels
In AutoCAD mode, this menu selection rotates the figure label. After choosing this command, select an
element or group of elements, and enter the desired rotation in degrees.
To access the Rotate Labels command, select Modify Elements from the Edit pull-down menu.

Modify Pressure Pipes
Pressure pipes have layout characteristics that are distinct from gravity pipes. The main difference is that
SewerCAD pressure pipes may follow a non-linear alignment (since in pressure systems, unlike gravity
runs, minor losses can be safely lumped with friction losses without significantly affecting model
accuracy). SewerCAD uses specialized commands for editing pressure pipes in AutoCAD.


Insert Bend - Use this command to add a bend to a pressure pipe. In AutoCAD, you will be prompted
to select a pipe to bend. Select the pipe and then select the location where you want the bend to appear.
The pipe alignment will automatically conform to this location.



Remove Bend - Use this command to remove a specific bend from a pressure pipe. In AutoCAD, you
will be prompted to select a pipe and, subsequently, the specific bend to remove.



Remove All Bends - Use this command to completely straighten a pressure pipe that contains bends.
In AutoCAD, you will be prompted to select a pipe and all bends will disappear.



Change Widths - This menu selection changes pipe widths. After choosing this command, select a
pipe or group of pipes and enter the desired width. Note that the width entered is equivalent to the
AutoCAD polyline width.

15.7 Working with Elements Using AutoCAD Commands
15.7.1

AutoCAD Commands
When running in AutoCAD mode, Haestad Methods’ products make use of all the advantages that
AutoCAD has, such as plotting capabilities and snap features. Additionally, AutoCAD commands can be
used as you would with any design project. For example, Haestad Methods’ elements and annotation can
be manipulated using common AutoCAD commands.

15.7.2

Explode Elements
In AutoCAD mode, running the AutoCAD Explode command will transform all Haestad Methods custom
entities into equivalent AutoCAD native entities. When a Haestad Methods custom entity is exploded, all
associated database information is lost. Be certain to save the exploded drawing under a separate filename.
Use Explode to render a drawing for finalizing exhibits and publishing maps of the model network. You
can also deliver exploded drawings to clients or other individuals who do not own a Haestad Methods
Product license, since a fully exploded drawing will not be comprised of any ObjectARX proxy objects.
See Working with Proxies for more information on this topic.

15.7.3

Moving Elements
When using AutoCAD mode, the AutoCAD commands Move, Scale, Rotate, Mirror, and Array can be
used to move elements. Refer to Selecting Elements for more details on this topic.
To move a node, execute the AutoCAD command either by typing it at the command prompt or selecting it
from the pull-down menu. Follow the AutoCAD prompts, and the node and its associated label will move
together. The connecting pipes will shrink or stretch depending on the new location of the node.

Chapter 15 – Additional Features of the AutoCAD Version

15.7.4

231

Moving Element Labels
When using AutoCAD mode, the AutoCAD commands Move, Scale, Rotate, Mirror, and Array can be
used to move element text labels. Refer to the help topics Selecting Elements and Working with Selections
in AutoCAD.
To move an element text label separately from the element, click the element label you wish to move. The
grips will appear for the label. Execute the AutoCAD command either by typing it at the command prompt
or selecting it off the tool palette. Follow the AutoCAD prompt, and the label will be moved without the
element.

15.7.5

Snap Menu
When using AutoCAD mode, the Snap menu is a standard AutoCAD menu that provides options for
picking an exact location of an object. Refer to the standard AutoCAD help documentation for more
information.

15.8 Undo / Redo
15.8.1

Undo and Redo Operations in AutoCAD
In AutoCAD, you have two types of Undo/Redo available to you. From the Edit menu, you have access to
SewerCAD Undo and Redo. Alternatively, you can perform the native AutoCAD Undo and Redo by
typing at the AutoCAD command line. The implementations of the two different operation types are quite
distinct.
The menu-based undo and redo commands operate exclusively on SewerCAD elements by invoking the
commands directly on the model server. The main advantage of using the specialized command is that you
will have unlimited undo and redo levels. This is an important difference, since in layout or editing it is
quite useful to be able to safely undo back and then redo ahead an arbitrary number of transactions. If you
use the native AutoCAD undo, you are limited to a single redo level. The SewerCAD undo/redo is also
faster than the native AutoCAD undo/redo. If you are rolling back SewerCAD model edits, it is
recommended that you use the menu-based undo/redo implementation.
Whenever you invoke a native AutoCAD undo, the model server will be notified when any SewerCAD
entities are affected by the operation. SewerCAD will then synchronize the model to the drawing state.
Wherever possible, the model will seek to map the undo/redo invocation onto the model server’s managed
command history. If the drawing state is not consistent with any pending undo or redo transactions held by
the server, SewerCAD will flush the command history. In this case, the model will synchronize the
drawing and server models in a rigorous fashion.
It is important to note that if you undo using the AutoCAD command and you end up restoring SewerCAD
elements that have been previously deleted, morphed, or split, some model state such as diameter or
elevations may be lost, even though the locational and topological state is fully consistent. This will only
happen in situations where the SewerCAD command history has been flushed. In such cases, you will be
warned to check your data carefully.

15.9 Converting Native AutoCAD Entities to SewerCAD Elements
15.9.1

Converting Native AutoCAD Entities
SewerCAD features powerful tools dedicated to assisting the user in building SewerCAD models from
existing AutoCAD drawing information. In addition to the standard ESRI Shapefile conversion options,

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Chapter 15 – Additional Features of the AutoCAD Version

there are two specific commands available in the AutoCAD platform that will be especially useful to the
AutoCAD modeler:

15.9.2



Layout Pipe Using Entity



Change Entities to Pipes

Layout Pipe Using Entity
In addition to the standard options available under the Pipe layout command (accessed by clicking on the
button in the SewerCAD Tools toolbar or by selecting using Tools / Layout / Pipe from the pulldown menu), you may elect to use an existing AutoCAD line, polyline, or arc as a template to define an
equivalent SewerCAD pipe or series of pipes.
While you are in the Pipe Layout command, you may invoke the Entity conversion option by using the
‘Entity’ keyword or by selecting ‘Entity’ from the right-mouse button context menu. Once selected, you
will be prompted to select an entity to use as a basis for a new pipe and conditionally specify the type of
nodal SewerCAD element(s) to use at each end of the pipe.
This command is extremely useful for constructing pressure pipes that follow a curved
alignment. In these cases use an arc as the defining template entity for the pipe creation.

15.9.3

Change Entities to Pipes
This special AutoCAD command allows you to use a selection of AutoCAD entities - arcs, lines, polylines,
and blocks - as a defining template set for the creation of equivalent SewerCAD elements. This command
performs the element generation in batch fashion. You are prompted for the selection of entities to convert,
and the selection is followed by the Polyline To Pipe Conversion Wizard that leads you through a
sequence of steps defining the basis of the batch conversion. The actual steps to be followed in the Wizard
are fully described in the AutoCAD Polyline to Pipe Conversion topic in the "Exchanging Data with CAD
software and AutoDesk Civil Design" chapter.
It is important to note that this is an automated batch process which requires some care and
attention with respect to the selection set that is going to be used as a basis for generating actual
SewerCAD model elements. Specifically, you probably want to process gravity sub-network
elements separately from pressure sub-network elements. It is also desirable to select like-sized
pipe elements during each pass. This way, you can use the prototyping capabilities to their
greatest advantage. A little time spent in planning and strategizing a series of individual
conversion steps will go a long way toward preventing confusion, which could necessitate later reconversions.

15.10 Special Considerations
15.10.1

Import SewerCAD
This is only available in the AutoCAD mode. This command imports a selected SewerCAD data (.SWR)
file for use in the current drawing. The new project file now corresponds to the drawing name, i.e.
CurrentDrawingName.SWR. Whenever you save changes to the network model through SewerCAD, the
new associated .SWR data file is updated and can be loaded into SewerCAD 5.0 or higher.
To import a SewerCAD model into AutoCAD, select File / Import / SewerCAD.

Chapter 15 – Additional Features of the AutoCAD Version

15.10.2

233

Working with Proxies
If you open a SewerCAD drawing file on an AutoCAD workstation that does not have the SewerCAD
application installed, you will get an AutoCAD Proxy Information message box. This is because the
executable logic for managing the AutoCAD entities is not available, and the SewerCAD modeling
elements are not associated with the SewerCAD native database.
SewerCAD proxy objects can be moved and erased. But doing so will put the drawing state out of sync
with the model database should the drawing be saved with its original name. If this happens, and you later
reload the drawing on an AutoCAD station that is running a SewerCAD application, the application will
automatically attempt to reconcile any differences it finds by automatically loading its Database
Synchronization routine.

Notes

Appendix A – Frequently Asked Questions

235

Appendix A
Frequently Asked Questions
A .1 Overview
To make your work easier, SewerCAD and the Help system are designed to be used together.
If you have a high resolution display monitor, you will probably find it helpful to size the frames of both
the program and the Help windows so that they fit side by side. Then, while using the program, you can
use the Help button in any dialog to update the Help window.
If the information you need is not on the How Do I page, click the Search button at the top of the Help
window to access the search index.

A .2 How Do I Control Element and Label Sizing?
To change the size of element symbols and labels:
1.

Select Tools / Options from the pull-down menus, and select the Drawing tab.

2.

In the Annotation Multipliers group, change the Symbol Size Multiplier to modify the element
size, and the Text Height Multiplier to modify the label size. Smaller numbers will make the
element symbols and text decrease in size.
These changes will affect all symbols and text, including color coding legends, but will not have any effect
on pipe lengths.

A .3 How Do I Reuse Deleted Element Labels?
To make the program reuse the label for a deleted element:
1.

Select Tools / Element Labeling from the pull-down menu.

2.

Enter the ID number for the deleted element in the Next field for the appropriate type of element.

3.

Click OK.

4.

Add a new element to the drawing.

A .4 How Do I Color Code Elements?
To color code elements:
1.

Select Tools / Color Coding... from the pull-down menu, or click the Color Coding (rainbow)
button on the toolbar.

2.

In the Color Coding dialog, select the attribute you would like to color code.

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Appendix A – Frequently Asked Questions
3.

Click the Initialize button to automatically build a range of colors. You may decide to modify
these default ranges.

4. Click OK to color code the drawing.
All link or node elements and their labels will be colored based on the specified ranges. You can also use
the Initialize button to quickly set up and modify Color Coding Options. A Color Coding Legend may
be inserted into the drawing by using the Legend tool located on the Tool Palette.

A .5 How Do I Remove Color Coding from Labels Imported from
Pre-v3.5 AutoCAD Files?
Due to popular request, Haestad Methods has implemented the separation of elements and their labels.
This gives you much more control over the placement and formatting of the labels, in addition to resolving
the problem of color coding labels with elements. However, if you open an old drawing (version 3.1 or
earlier) with existing color coding on the labels, this color coding will not dynamically update.
The solution to this problem is to move the labels to a different layer, and assign a neutral color to them.
To do this, select Tools / Element Properties from the pull-down menus, and choose the Labels tab.
Assign a new layer to the labels for all the elements, and check Apply to Existing Objects.

A .6 How Do I Do a Profile Plot?
The Profile Plot window includes the selected upstream element and all elements linked in a direct
downstream path to the outlet. There are two ways to open a Profile Plot window:


Select Tools / Profiling from the pull-down menu to open the Profiles Manager. From here you can
go through the Profile Wizard, by clicking the Profile Management button and selecting Add.

or


Right-click an element, and select Create Profile On… from the pop-up menu. This will open up the
Profile Wizard with all elements downstream of the selected element included in the list of elements
to be profiled.
The Options button allows you to control the display of detail layers in the Profile Window.

A .7 How Do I Change Units in a Column?
In a Table you may change the units of all the data within any column. To change the units:
1.

Select Use Local Units from the Options menu in the Tabular Report dialog.

2.

Right-click the column heading, or any data item within a column.

3.

Select Properties from the pop-up menu.

4.

Change the units and select OK. All data items in that column will change to the selected units.

The change of units affects only the data in the Table. It DOES NOT change the units within
your network design.

Appendix A – Frequently Asked Questions

237

A .8 How Do I Access the Haestad Methods Knowledge Base?
You can access of hundreds of commonly asked questions at our online Knowledge Base.
The quickest way to access the Knowledge Base is to click the Globe Icon
in the product toolbars.
This will automatically log you on to our website. Simply click the Knowledge Base icon next to the
Haestad product of interest.
If the computer you are using does not have internet access, you can log on to Knowledge Base at an
alternate computer by going to "http://www.haestad.com" and entering the ClientCare portion of the
website. You can then logon with the Product ID located in the back of the User’s Manual or your PID
number.

A .9 How do I Model an Inverted Siphon (Depressed Sewer)?
There is no real trick to modeling an inverted siphon in SewerCAD. The inverted siphon consists of two or
more gravity pipes (depending on changes of slope) that will be surcharged. Simply create pipes sloping
downward and upward connected at a central junction. The gradually varied flow algorithm is robust
enough to handle adverse slopes.
You can apply any bend losses to the central junction as a standard headloss. If you feel that friction losses
are the predominant loss you can assume no headloss at the central junction. The central junction on the
siphon (which may not be real) needs to be bolted or extend above the ground, so the hydraulic grade line is
not reset if it exceeds the manhole’s top.
If the siphon has multiple barrels in parallel, such that one takes the low flow and others come on line as
flow increases, then it may be necessary to create a different physical alternatives for each possible number
of pipes and replace the siphon by the equivalent pipe size in each alternative, or to use the diversion
feature. See the Gravity Flow Diversions Technical Supplement for more information on setting up
diversions and equivalent pipes.

Notes

Appendix B – SewerCAD Theory

239

Appendix B
SewerCAD Theory
B .1 Overview
This appendix provides an overview of the methods that SewerCAD uses to compute flows and hydraulic
grades throughout the system, including both gravity and pressure computations.
Some of the basic concepts underlying the calculations are as follows:


SewerCAD can run both Steady State and Extended Period Analyses. Steady State Analyses model a
single instant in time and are generally used to model a network under peak loading conditions.
Extended Period Simulations model a network over a specified duration of time and can be used to
model hydrograph loading, wet well capacities, and automated pump behavior.



Loads are the sources of flow in the sanitary sewer system, and are categorized as sanitary (dry
weather) loads, wet weather loads, and known loads. The total load at any given point may be a
combination of these basic load types.



Loads can be adjusted through the use of fixed or variable peaking factors during a Steady State
analysis in order to analyze the system under a variety of conditions, such as daily average, minimum,
and maximum scenarios. Common pre-defined variable peaking methods are included, but you may
also specify your own as tables or equations.



Loads can also be varied over time using loading patterns and hydrographs during an Extended Period
Simulation.



Gravity pipe headlosses are computed based on gradually varied flow profiles or approximate profiles.
Either of these profile methods allows for free-surface (open channel) flow, full flow (as for a pipe that
is submerged), and mixed conditions. Pressure pipe headlosses are based strictly on full-flow
hydraulics.



Gravity structure losses may be based on several common methodologies. Where appropriate, these
calculations may account for pipe bend angles, structure benching, and other influential factors.



During an Extended Period Simulation hydrographs are routed through the gravity pipes to account for
translation and other effects.



All or portions of gravity systems may be selected for automatic design. This preliminary design can
be used to set pipe and structure elevations, as well as to size the pipes.

B .2 Loading
SewerCAD classifies loads as sanitary (dry weather) loads, wet weather loads, and known loads.
Sanitary loads correspond to loads that result from human activity, and are not weather-dependent.
Common sources of sanitary loads are various residential, commercial, recreational, and industrial usage.

240

Appendix B – SewerCAD Theory

Wet weather loads are related to rainfall activity, such as groundwater infiltration (water leaking into a pipe
through cracks, joints, and other defects) and structure inflow (surface water entering a structure through
the cover).
Known loads are typically used to model flows that have already been gathered from some other source,
such as external calculations or field measurements.
In addition to these basic load types, there are also pumped loads. Pumped loads are special kinds of loads
that represent sewage pumped into the gravity system via force mains. Pumped loads are optionally
determined during calculations, and cannot be input directly.

B.2.1

Common Load Types
There are two different loading types that can be applied as both wet weather and sanitary loads. The
behavior of each loading type is the same regardless of how it is applied. The two common loads are:


Hydrographs



Pattern Loads

Hydrographs
In SewerCAD you can enter time vs. flow data directly as a load. The hydrographs will then be directly
added to any other loads coming to that point and then routed downstream
During a Steady State analysis a hydrograph loaded can be converted into a single load based on one of the
following selected Steady State Loading options.


Peak - The peak of the hydrograph will be used as the Steady State load.



Average - The average of the hydrograph flows will be used as the Steady State load.



Minimum - The minimum flow of the hydrograph will be used as the Steady State load.



Zero - The hydrograph is disregarded during the Steady State run.
The final flow of the hydrograph will remain constant for the duration of the simulation.
The Steady State Loading options are accessed by clicking the Options button on the Scenario /
GO dialog.

Pattern Loads
A pattern load is comprised of a base load and an associated loading pattern. The pattern is a series of
multipliers, which describes how the base load varies over time.
During a Steady State Analysis the entered base load is used as the load regardless of the applied loading
pattern.
Extreme Flow Factors are not applied to entered base loads.

Hydrographs vs. Pattern Loads
Hydrographs and Pattern loads are two distinct ways to describe how flow varies over time. Ultimately,
you can attain the same results using either method but there are some behavioral and semantic differences
that should be noted.
Pattern loads consists of a single average base load and a series of dimensionless multipliers used to
delineate how the load varies over time. A hydrograph, simply, is a time-discharge series.

Appendix B – SewerCAD Theory

241

Hydrographs are usually applied as wet weather loads, and are generated using hydrologic methods, while
patterns are more typically applied to sanitary loads. Patterns are developed based on predetermined
variations in loading over the course of a day. The patterns are then assumed to represent templates for
how the loads of a similar type vary over time. These statements represent typical usage of both loading
types; they do not represent hard and fast rules.
During an Extended Period Simulation if the duration of the simulation exceeds the duration of a pattern
then the pattern will repeat itself. If the duration of the simulation exceeds the duration of a hydrograph the
last point of the hydrograph will remain constant for the extent of the remaining time.

B.2.2

Sanitary (Dry Weather) Loading
The total sanitary load may be comprised of an unlimited number of individual sanitary loads. For
example, the local load for a given manhole may be a combination of loads from an apartment building, a
gas station, and a film development store, each with different loading characteristics. They can either be
entered as:


Unit Sanitary Loads



Pattern Loads


Hydrographs
Unit sanitary loads and pattern loads are calculated or entered as a base load, which represent the average
loading on the system at that point. During a Steady State analysis the unit sanitary loads can be adjusted
to represent peak or minimum loads using the Extreme Flow Factor methods. During an Extended Period
Simulation a loading pattern can be applied to both the unit sanitary loads and pattern loads to described
how the base load varies over time.
Hydrographs can also be applied as sanitary loads. They are meant to represent actual measured flow or
hydrographs generated from other programs, and SewerCAD does not apply peaking factors or patterns to
them.

Unit Sanitary (Dry Weather) Loads
Unit sanitary (dry weather) loads are entered based on a number of contributing units, with a specified
average load per unit, such as X-amount of flow per apartment resident. With each load type, you can then
associate a peaking factor method or a loading pattern, allowing you to account for the knowledge that
peaking factors and patterns are most likely different for residential and commercial areas.
Peaking factors are applied only during the Steady State analyses. During Extended Period Simulations
loading patterns can be applied to the base loads generated from the unit sanitary loads to account for
variations in sanitary inflow over time.

Extreme Flow Factor
Sewer design and analysis generally considers a variety of loading conditions, such as minimum, average,
and peak conditions. Base (average) sanitary loads are transformed into minimum or peak loads using an
Extreme Flow Factor.
The most common type of Extreme Flow Factor (EFF) is the Variable Peaking Factor (PF).
Qpeaked = Qbase * EFF
Where:

Qpeaked = Transformed flow (l/s, gpm)
Qbase

= Base flow (l/s, gpm)

EFF

= Extreme Flow Factor (unitless)

242

Appendix B – SewerCAD Theory

Extreme Flow Factor methods are only used during Steady State analyses. During Extended
Period Simulations loading patterns can be applied to the Unit Dry Weather base loads.

Common Variable Peaking Factors
Some of the most common variable peaking factor (PF) calculation methods are:
Babbitt

PF =

Where:

5 .0
 P 


 1000 
P

=

0.20

Contributing population (number of capita)

Harmon

PF = 1.0 +

Where:

14.0
 P 
4 .0 + 

 1000 

P

=

0.50

Contributing population (number of capita)

Ten States Standard (Great Lakes Upper Mississippi River Board)

P
1000
PF =
P
4+
1000
18 +

Where:

P

=

Contributing population (number of capita)

=

Base sanitary load (l/s)

Fedorov

PF =

2.69
Q 0.121

Where:

Q

The Babbit peaking method does not converge to 1. For populations larger than 3,125,000 the
peaking factor will become smaller than 1.

B.2.3

Wet Weather Loading
The Wet Weather Load represents the intrusion of rainfall water into the sewer system. Wet weather loads
consist of groundwater infiltration, rainfall inflow, and illegal sump pump connections. Groundwater
infiltration occurs in gravity pipes, while inflow occurs at manholes, pressure junctions, and wet wells.

Appendix B – SewerCAD Theory

243

Infiltration loads refer to wet weather loads entering pipes, where water leaks into the system through
joints, cracks, and other defects. Inflow loads refer to wet weather loads entering structures, typically
surface water entering through a structure's cover.

Infiltration
Infiltration resulting from the presence of groundwater can be modeled for gravity pipes. It is combined
with the loads at the upstream end of the pipe to determine the pipe's Total Wet Weather Flow.
There are several common methods of determining infiltration based on pipe characteristics, which is why
SewerCAD allows infiltration to be defined with any of the following methods:


Proportional to Pipe Length - The infiltration is specified as an Infiltration Rate per Unit of Pipe
Length.



Proportional to Pipe Diameter-Length - The infiltration is specified by an Infiltration Rate per Unit
of Pipe Diameter times Pipe Length. The amount of infiltration is proportional to the pipe length and
to the pipe diameter.



Proportional to Pipe Surface Area - The infiltration is specified by an Infiltration Rate per Unit of
Pipe Surface Area, where the pipe's surface area is calculated as its length multiplied by its full
perimeter. The amount of infiltration is proportional to the pipe length and the pipe diameter.



Proportional to Count - The infiltration is specified by count value, which may be the number of
defects in the pipe, and the Infiltration Rate per Unit of Count.



Additional Infiltration - Fixed amount of infiltration that is added to the total wet weather load. This
value is constant regardless of the pipe's characteristics.



Hydrographs - The infiltration is specified as a table of flow vs. time.

• Pattern Loads - The infiltration is specified as an average base load and a loading pattern.
During an Extended Period Simulation the five non-time-based methods will generate a single straight-line
hydrograph producing a constant load for the duration of the simulation.

Inflow
Inflow loads refer to wet weather loads entering structures, which are typically from surface water entering
through a structure's cover, or pumped illegally into a force main system. Inflows can be entered as the
following loading types:


Hydrographs

• Pattern Loads
During Steady State analysis these loads can be modeled, and are combined with upstream wet weather
loads to determine the Total Wet Weather Flow.
During Extended Period Simulations the loads are not classified once they enter the system they are added
to together as a single lump hydrograph.
Inflows can be applied to manholes, wet wells, and pressure junctions.

B.2.4

Known Loading
Known loads are a special type of fixed load. As with other fixed loads, known loads remain constant as
they progress downstream and combine directly as a simple sum.
The special behavior of known loads occurs during a Steady State Analysis when another known load is
specified at a downstream location. While most fixed loads combine directly under any circumstances, a
non-zero known load at any location replaces all upstream known loads.

244

Appendix B – SewerCAD Theory

For this reason, known loads may be desirable for modeling loads that originate from external calculations
or field measured data (loads that do not require SewerCAD to generate or sum them in any way).
During Extended Period Simulations, Known Flows are modeled as a single constant flow hydrograph over
the duration of the simulation. They are added directly to the existing flows coming from upstream sources
and are all lumped together as a single hydrograph for routing. The Known Flows are additive and do
not replace each other during Extended Period Simulations.

B .3 Gravity Pipe Hydraulics
B.3.1

Basic Concepts
This documentation is intended to familiarize you with some of the methods used in this program’s
calculations. However, there is not a great deal of time spent on common hydraulic terms and equations,
such as determination of wetted perimeter, hydraulic radius, hydraulic depth, and Reynolds number.

B.3.2

Hydraulics and Energy Grades
The Energy Principle
The first law of thermodynamics states that for any given system, the change in energy is equal to the
difference between the heat transferred to the system and the work done by the system on its surroundings
during a given time interval.
The energy referred to in this principle represents the total energy of the system minus the sum of the
potential, kinetic, and internal (molecular) forms of energy, such as electrical and chemical energy. The
internal energy changes are commonly disregarded in water distribution analysis because of their relatively
small magnitude.
In hydraulic applications, energy is often represented as energy per unit weight, resulting in units of length.
Using these length equivalents gives engineers a better feel for the resulting behavior of the system. When
using these length equivalents, the state of the system is expressed in terms of head. The energy at any
point within a hydraulic system is often represented in three parts:


Pressure Head:

p/γ



Elevation Head:

z



Velocity Head:

V2/2g

Where:

p =

Pressure (N/m2, lb/ft2)

γ =

Specific weight (N/m3, lb/ft3)

z =

Elevation (m, ft)

V =

Velocity (m/s, ft/s)

g =

Gravitational acceleration constant (m/s2, ft/s2)

These quantities can be used to express the headloss or head gain between two locations using the energy
equation.

The Energy Equation
In addition to pressure head, elevation head, and velocity head, there may also be head added to the system,
by a pump for instance, and head removed from the system due to friction. These changes in head are
referred to as head gains and headlosses, respectively. Balancing the energy across two points in the
system, we then obtain the energy equation:

Appendix B – SewerCAD Theory

245

2

2

p1
V
p
V
+ z1 + 1 + h p = 2 + z 2 + 2 + h L
γ
2g
γ
2g
Where:

p =

Pressure (N/m2, lb/ft2)

γ =

Specific weight (N/m3, lb/ft3)

z =

Elevation at the centroid (m, ft)

V =

Velocity (m/s, ft/s)

g =

Gravitational acceleration constant (m/s2, ft/s2)

hp =

Head gain from a pump (m, ft)

hL = Combined headloss (m, ft)
The components of the energy equation can be combined to express two useful quantities, which are the
hydraulic grade and the energy grade.

Hydraulic and Energy Grades
Hydraulic Grade
The hydraulic grade is the sum of the pressure head ( p/γ ) and elevation head ( z ). The hydraulic head
represents the height to which a water column would rise in a piezometer. The plot of the hydraulic grade
in a profile is often referred to as the hydraulic grade line, or HGL.
Energy Grade
The energy grade is the sum of the hydraulic grade and the velocity head ( V2/2g ). This is the height to
which a column of water would rise in a pitot tube. The plot of the hydraulic grade in a profile is often
referred to as the energy grade line, or EGL. At a lake or reservoir, where the velocity is essentially zero,
the EGL is equal to the HGL, as can be seen in the following figure.

EGL and HGL

B.3.3

Friction Loss Methods
There are many equations that approximate friction losses associated with the flow of liquid through a
given section. Commonly used friction methods include:


Chezy's Equation



Kutter’s Equation



Manning’s Equation

246

Appendix B – SewerCAD Theory



Darcy-Weisbach Equation



Colebrook-White Equation

• Hazen-Williams Equation
Friction losses are generally based on the relationships between fluid velocity, section roughness, depth of
flow, and the friction slope (headloss per unit length of conduit).

Chezy's Equation
Chezy’s equation is rarely used directly, but it is the basis for several other methods, including Manning’s
equation and Kutter’s equation. Chezy’s equation is:

Q =C⋅A ⋅ R⋅S
Where:

Q =

Discharge in the section (m³/s, cfs)

C =

Chezy’s roughness coefficient (m1/2/s, ft1/2/s)

A =

Flow area (m², ft²)

R =

Hydraulic radius (m, ft)

S =

Friction slope (m/m, ft/ft)

Kutter's Equation
Kutter’s equation can be used to determine the roughness coefficient in Chezy’s formula, and is most
commonly used for sanitary sewer analysis. Kutter’s equation is as follows:

k2 k3
+
S
n
C=
k 
n 
⋅  k1 + 2 
1+
S 
R 
k1 +

Where:

C =

Chezy’s roughness coefficient(m1/2/s, ft1/2/s)

S =

Friction slope (m/m, ft/ft)

R =

Hydraulic radius (m, ft)

n =

Kutter’s roughness (unitless)

k1 =

Constant (23.0 for SI, 41.65 for US)

k2 =

Constant (0.00155 for SI, 0.00281 for US)

k3 =

Constant (1.0 for SI, 1.811 for US)

Kutter’s roughness coefficients are the same as Manning’s roughness coefficients.

Manning's Equation
Manning's equation is one of the most popular methods in use today for free surface flow (and, like
Kutter’s equation, is based on Chezy’s equation). For Manning’s equation, the roughness coefficient in
Chezy’s equation is calculated as:

C=k⋅
Where:

R1/ 6
n
C =

Chezy’s roughness coefficient (m1/2/s, ft1/2/s)

Appendix B – SewerCAD Theory
R =

Hydraulic radius (m, ft)

n =

Manning’s roughness (s/m1/3)

k =

Constant (1.00 m1/3/m/13, 1.49 ft1/3/m1/3)

247

Substituting this roughness into Chezy’s equation, we obtain the well-known Manning’s equation:

Q=

k
⋅ A ⋅ R2 / 3 ⋅ S1/ 2
n

Where:

Q =

Discharge (m³/s, cfs)

k =

Constant(1.00 m1/3/m/13, 1.49 ft1/3/m1/3)

n =

Manning’s roughness (s/m1/3)

A =

Flow area (m², ft²)

R =

Hydraulic radius (m, ft)

S =

Friction slope (m/m, ft/ft)

Manning’s roughness coefficients are the same as the roughness coefficients used in Kutter’s
equation.

Darcy-Weisbach Equation
Because of non-empirical origins, the Darcy-Weisbach equation is viewed by many engineers as the most
accurate method for modeling friction losses. It most commonly takes the following form:

hf = f ⋅

Where:

L V2
D 2g
hf =

Headloss (m, ft)

f

Darcy-Weisbach friction factor (unitless)

=

D =

Pipe diameter (m, ft)

L =

Pipe length (m, ft)

V =

Flow velocity (m/s, ft/s)

g = Gravitational acceleration constant (m/s², ft/s²)
For section geometries that are not circular, this equation is adapted by relating a circular section’s fullflow hydraulic radius to its diameter:
D = 4R
Where:

R =

Hydraulic radius (m, ft)

D = Diameter (m, ft)
This can then be rearranged to the form:

Q = A ⋅ 8g ⋅

R⋅S
f

248

Appendix B – SewerCAD Theory
Where:

Q =

Discharge (m³/s, cfs)

A =

Flow area (m², ft²)

R =

Hydraulic radius (m, ft)

S =

Friction slope (m/m, ft/ft)

f

Darcy-Weisbach friction factor (unitless)

=

g = Gravitational acceleration constant (m/s², ft/s²)
The Swamme and Jain equation can then be used to calculate the friction factor.
Swamme and Jain Equation:

f=

1.325
 

ln k 3.7D + 5.74 0.9 
R e 
 

Where:

f

2

=

Friction factor (unitless)

k =

Roughness height (m, ft)

D =

Pipe diameter (m, ft)

Re =

Reynolds number (unitless)

The friction factor is dependent on the Reynolds number of the flow, which is dependent on the flow
velocity, which is dependent on the discharge. As you can see, this process requires the iterative selection
of a friction factor until the calculated discharge agrees with the chosen friction factor.
The Kinematic Viscosity is used in determining the friction coefficient in the Darcy-Weisbach
Friction Method. The default units are initially set by Haestad Methods.

Colebrook-White Equation
The Colebrook-White equation is used to iteratively calculate for the Darcy-Weisbach friction factor:
Free Surface

1
f

= −2 log(

k
2.51
+
)
14.8R R e f

Full Flow (Closed Conduit)

1
f

= −2 log(

Where:

k
2.51
+
)
12.0R Re f

Re =

Reynolds Number (unitless)

k =

Darcy-Weisbach roughness height (m, ft)

f

=

Friction factor (unitless)

R =

Hydraulic radius (m, ft)

Appendix B – SewerCAD Theory

249

Hazen-Williams Equation
The Hazen-Williams Formula is frequently used in the analysis of pressure pipe systems (such as water
distribution networks and sewer force mains). The formula is as follows:

Q = k ⋅ C ⋅ A ⋅ R0.63 ⋅ S0.54
Where:

B.3.4

Q =

Discharge in the section (m³/s, cfs)

C =

Hazen-Williams roughness coefficient (unitless)

A =

Flow area (m², ft²)

R =

Hydraulic radius (m, ft)

S =

Friction slope (m/m, ft/ft)

k =

Constant (0.85 for SI, 1.32 for US).

Flow Regime
The hydraulic grade in a flow section depends heavily on the tailwater conditions, pipe slope, discharge,
and other conditions. The basic flow regimes that a pipe may experience include:


Pressure Flow



Uniform (Normal) Flow



Critical Flow



Subcritical Flow



Supercritical Flow
Based on the gradually varied flow analysis, different portions of any given pipe may be under
different flow regimes.

Pressure Flow
When a pipe is surcharged, headlosses are simply based on the full barrel area and wetted perimeter.
Because these characteristics are all functions of the section shape and size, friction loss calculations are
greatly simplified by pressurized conditions.

Uniform Flow and Normal Depth
Uniform flow refers to a hydraulic condition where the discharge and cross-sectional area, and therefore the
velocity, are constant throughout the length of the channel or pipe. For a pipe flowing full, all that this
requires is that the pipe be straight and have no contractions or expansions. For a non-full section,
however, there are a few additional points of interest:




In order for the cross-sectional area to remain the same, the depth of flow must be constant throughout
the length of the channel. This requires that the friction slope equal the constructed slope. This depth
is called normal depth.

Since the hydraulic grade line parallels the invert of the section and the velocity does not change, the
energy grade line is parallel to both the hydraulic grade line and the section invert under uniform flow
conditions.
In prismatic channels, flow conditions will typically approach normal depth if the channel is sufficiently
long.

250

Appendix B – SewerCAD Theory

Critical Flow, Critical Depth, and Critical Slope
Critical flow occurs when the specific energy of the section is at a minimum. This condition is defined by
the situation where:

A3 Q2
=
T
g
Where:

A =

Area of flow (m², ft²)

T =

Top width of flow (m, ft)

Q =

Section discharge (m³/s, ft³/s)

g = Gravitational acceleration (m/s²,ft/s²)
This is a relatively simple computation for simple geometric shapes, but can require iterative calculation for
more complex shapes (such as arches). Some sections may even have several valid critical depths, making
numerical convergence more difficult.
Critical depth refers to the depth of water in a channel for which the specific energy is at its minimum.
Critical slope refers to the slope at which the critical depth of a pipe would be equal to the normal depth.
Subcritical Flow
Subcritical flow refers to any flow condition where the Froude number is less than 1.0. For this condition,
the depth is above critical depth, and the velocity is below the critical depth velocity.
Supercritical Flow
Supercritical flow refers to any condition where the Froude number, or the ratio of internal forces to gravity
forces, is greater than 1.0. For this condition, the depth is below critical depth, and the velocity is above the
critical depth velocity.

B.3.5

Gradually Varied Flow Analysis
For free surface flow, depth rarely remains the same throughout the length of a channel or pipe. Starting
from a boundary control depth, the depth changes gradually, increasing or decreasing until normal depth is
achieved (if the conduit is sufficiently long). The determination of a boundary control depth depends on
both the tailwater condition and the hydraulic characteristics of the conduit. The areas of classification for
gradually varied flow analysis are:


Slope Classification



Zone Classification



Profile Classification

Slope Classification
The constructed slope of a conduit is a very important factor in determining the type of gradually varied
flow profile that exists. Slopes fall into one of five types, all of which are handled by the program:


Adverse Slope



Horizontal Slope



Hydraulically Mild Slope



Critical Slope



Hydraulically Steep Slope

Appendix B – SewerCAD Theory

251

Any pipe can qualify as only one of these slope types for a given discharge. For differing flows, though, a
pipe may change between qualifying as a mild, critical, and steep slope. These slopes do not relate to just
the constructed slope, but to the constructed slope relative to the critical slope for the given discharge.
Adverse Slope
Adverse slope occurs when the upstream invert elevation of a pipe is actually below the downstream invert
elevation. Normal depth is undefined for adverse slopes, since no amount of positive flow would result in a
rising friction slope. Most flow conditions for adverse sloping pipes are subcritical.
Pipes are typically not designed to be adverse, so most situations with adverse slopes are due to
construction errors or other unusual circumstances. Adverse pipes may cause some concern beyond the
hydraulic capacity of the system, because stagnant water, excessive clogging, and other non-desirable
conditions may result.
Horizontal Slope
As the name suggests, a horizontal slope results when a pipe’s upstream and downstream invert elevations
are the same. Normal depth for a horizontal pipe is theoretically infinite, although critical depth may still
be computed. Like adverse slopes, most flow conditions for horizontal pipes are subcritical.
Hydraulically Mild Slope
A hydraulically mild slope is a condition where the constructed slope is less than the critical slope. For this
condition, the section’s normal depth is above critical depth, and the flow regime is usually subcritical.
Critical slope
A pipe or channel may have exactly the same slope as the critical slope for the discharge it carries. This is
a very uncommon occurrence, but it is possible and the program does calculate it appropriately. Critical
depth is an inherently unstable surface, so flow is most likely to be subcritical for these slopes.
Hydraulically Steep Slope
A hydraulically steep slope is a condition where the constructed slope is greater than the critical slope.
For this condition, the section’s normal depth is below critical depth, and the flow regime is usually
supercritical. However, high tailwater conditions may cause flow to be subcritical.

Zone Classification
There are three zones that are typically used to classify gradually varied flow:


Zone 1 is where actual flow depth is above both normal depth and critical depth.



Zone 2 is where actual flow depth is between normal depth and critical depth.



Zone 3 is where actual flow depth is below both normal depth and critical depth.

Profile Classification
The gradually varied flow profile classification is simply a combination of the slope classification and the
zone classification. For example, a pipe with a hydraulically mild slope and flow in zone 1 would be
considered a Mild-1 profile (M1 for short). The program will analyze most profile types, but will not
analyze certain flow profile types that occur rarely in conventional sewer system such as H3, M3, and S3.

252

Appendix B – SewerCAD Theory
Profile Classification

B.3.6

Energy Balance
Even for gradually varied flow, the solution is still a matter of balancing the energy between the two ends
of a pipe segment. The energy equation as it relates to each end of a segment is as follows (note that the
pressures for both ends are zero, since it is free surface flow):

Z1 +

V12
V2
= Z2 + 2 + H L
2g
2g

Where:

Z1 =

Hydraulic grade at upstream end of the segment (m, ft)

V1 =

Velocity at the upstream end (m/s, ft/s)

Z2 =

Hydraulic grade at the downstream end of the segment (m, ft)

V2 =

Velocity at the downstream end (m/s, ft/s)

HL =

Loss due to friction - other losses are assumed to be zero (m, ft)

g = Gravitational acceleration constant (m/s², ft/s²)
The friction loss is computed based on the average rate of friction loss along the segment and the length of
the segment. This relationship is as follows:

Appendix B – SewerCAD Theory

H L = S Avg ⋅ ∆x =
Where:

253

S1 + S 2
∆x
2

HL =

Loss across the segment (m, ft)

Savg

=

S1 =

Friction slope at the upstream end of the segment (m/m, ft/ft)

Average friction slope (m/m, ft/ft)

S2 = Friction slope at the downstream end of the segment (m/m, ft/ft)
Dx = Length of the segment being analyzed (m, ft)
The conditions at one end of the segment are known through assumption or from a previous calculation
step. Since the friction slope is a function of velocity, which is a function of depth, the depth at the other
end of the segment can be found through iteration. There are two primary methods for this iterative
solution, the Standard Step method and the Direct Step method.

Standard Step Method
The standard step method of gradually varied flow energy balance involves dividing the channel into
segments of known length and solving for the unknown depth at one end of the segment, starting with a
known or assumed depth at the other end. The standard step method is the most popular method of
determining the flow profile because it can be applied to any channel, not just prismatic channels.

Direct Step Method
The direct step method is based on the same basic energy principles as the standard step method, but takes
a slightly different approach towards the solution. Instead of assuming a segment length and solving for
the depth at the end of the segment, the direct step method assumes a depth and then solves for the segment
length.
Because it generates better resolution within the changing part of the profile, the gravity flow algorithm of
StormCAD and SewerCAD primarily use the direct step method to compute gradually varied flow profiles.

B.3.7

Mixed Flow Profiles
Although the hydraulic slope of a pipe will be the same throughout its length, a pipe may contain several
different profile types. The transitions that may be encountered include:


Sealing (Surcharging) Conditions



Rapidly Varied Flow (Hydraulic Jumps)

Sealing (Surcharging) Conditions
There may be conditions such that part of the section is flowing full, while part of the flow remains open.
These conditions are called sealing conditions, and the sections are analyzed in separate parts. For sealing
conditions, the portion of the section flowing full is analyzed as pressure flow, and the remaining portion is
analyzed with gradually varied flow techniques.

Rapidly Varied Flow
Rapidly varied flow is turbulent flow resulting from the abrupt and pronounced curvature of flow
streamlines into or out of a hydraulic control structure. Examples of rapidly varied flow include hydraulic
jumps, bends, and bridge contractions.
The hydraulic phenomenon that occurs when the flow passes rapidly from supercritical to subcritical flow
is called a hydraulic jump. The most common occurrence of this within a gravity flow network occurs
when there is a steep pipe discharging into a particularly high tailwater, as shown in the following figure.

254

Appendix B – SewerCAD Theory
Hydraulic Jump

There are significant losses associated with hydraulic jumps, due to the amount of mixing and hydraulic
turbulence that occurs. These forces are also highly erosive, so engineers typically try to prevent jumps
from occurring in gravity flow systems, or at least try to predict the location of these jumps in order to
provide adequate channel, pipe, or structure protection. The program does not perform any specific force
analyses that seek to precisely locate the hydraulic jump, nor does it identify the occurrence of jumps that
might happen as flows leave a steep pipe and enter a mild pipe. Rather it performs analyses sufficient to
compute grades at structures.

B.3.8

Backwater Analysis
The classic solution of gravity flow hydraulics is via a backwater analysis. This type of analysis starts at
the network outlet under free discharge, submerged, or tailwater control, and proceeds in an upstream
direction.
Steep pipes tend to "interrupt" the backwater analysis, and reset the hydraulic control to critical depth at the
upstream end of the steep pipe. A frontwater analysis may be needed for a steep profile (such as an S2),
with the backwater analysis recommencing from the upstream structure.

Free Outfall
This program lets you define the tailwater condition at the outlet as either Free Outfall, Crown Elevation or
User-Specified.
For a pipe with a hydraulically steep slope, the Free Outfall condition will yield a starting depth equal to
normal depth in the pipe. For a pipe with a hydraulically mild slope, the Free Outfall condition will yield a
starting depth equal to critical depth. When an outlet has multiple incoming pipes, the Free Outfall
condition yields a starting elevation equal to the lowest of the individual computed elevations.
The Crown condition should be used when the pipe discharges to an outlet where the water surface
elevation is equal to the elevation of the top of the pipe.

Structure Flooding
Flooding at manholes in SewerCAD and inlets in StormCAD occurs whenever the elevation of water is
above the structure rim elevation. When this occurs, the backwater analysis will continue by resetting the
hydraulic grade to the structure rim elevation or ground elevation, whichever is higher. However, if a
structure is defined with a bolted cover, the hydraulic grade is not reset to the rim elevation.
In actual flooding situations, flows may be diverted away from the junction structure and out of the system,
or attenuated due to surcharged storage. In this program, even though the governing downstream boundary
for the next conduit is artificially lowered to prevent the propagation of an incorrect backwater, the peak
discharges at the structure are conserved and are not reduced by the occurrence of flooding at a junction.

B.3.9

Frontwater Analysis
The program will perform a frontwater analysis in a steep pipe operating under supercritical flow, since
these pipes are typically entrance controlled. The hydraulic control is at the upstream end of the conduit,
and the gradually varied flow analysis will proceed in a downstream direction until either the normal depth
is achieved, a hydraulic jump occurs, or the end of the pipe is encountered.

Appendix B – SewerCAD Theory

255

The program’s algorithm is fundamentally based on backwater analysis. As a result, a
continuous frontwater analysis is not performed through two or more consecutive steep pipes.
This is a performance trade-off that has little impact in evaluating performance of the collection
system in most situations. The assumption of critical depth at the upstream end results in a
conservative depth in all cases, and is exactly correct at the point of the steep run furthest
upstream.

B.3.10

Pipe Average Velocity
Average Velocity Methods
Several common methods for computing a pipe’s average velocity are available:


Uniform Flow Velocity



Full Flow Velocity



Simple Average Velocity



Weighted Average Velocity

Uniform Flow Velocity
The uniform flow velocity of a pipe is obtained by calculating the velocity in the pipe at normal depth. If
the normal depth corresponds to a surcharged condition, the full flow velocity is used instead.

Full Flow Velocity
The full flow velocity corresponds to the velocity when the pipe is flowing full. The flow area is equal to
the entire cross-sectional area of the pipe.

Simple Average Velocity
The simple average velocity is computed by:

Va =

Vu + Vd
2

Where:

Va = Average velocity (m/s, ft/s)
VU = Upstream velocity (m/s, ft/s)
Vd = Downstream velocity (m/s, ft/s)

The Simple Average Velocity method does not account for any depth changes between the two
ends of the pipe as the weighted average velocity method does.

Weighted Average Velocity
To compute the weighted average velocity, the simple average velocity of each profile segment is
considered and given a weight based on its length:
n V + V
di
Va = ∑  ui
i =1 
2

  Li
 ⋅ 
  Lt






256

Appendix B – SewerCAD Theory
Where:

Va =

Average velocity for the pipe (m/s, ft/s)

Vui =

Upstream velocity for segment i (m/s, ft/s)

Vdi =

Downstream velocity for segment i (m/s, ft/s)

Li =

Length of the profile segment i (m, ft)

Lt =

Total length of the pipe (m, ft)

Pipe Average Velocity and Travel Time
The travel time though each pipe is computed as:

t = L/V
Where:

B.3.11

t

=

Time of travel through the pipe (s)

V =

Average velocity though the pipe (m/s, ft/s)

L =

Length of the pipe (m, ft)

Capacity Analysis (Approximate Profiles)
Traditionally, gravity pipe analyses and designs have not included the calculation-intense process of
estimating a gradually varied flow profile. With this program, you have the option of determining
discharge using gradually varied flow, or using the more traditional Capacity Analysis option. Capacity
analysis still uses a backwater approach, with the profile type for a pipe being primarily dependent on the
pipe's full flow capacity and downstream hydraulic grade.
The capacity analysis is advantageous over the gradually varied flow analysis in terms of processing time.
If you are dealing with a relatively large network and you wish to arrive quickly at reasonable
approximation then the capacity analysis is the way to go. The gradually varied flow algorithms are more
rigorous and generate solutions that more closely reflect reality.
There are two basic approximate profile cases: the Full Capacity Profile and the Excess Capacity Profile.
Full Capacity Profiles
Full capacity profiles occur when the pipe's actual discharge is greater than or equal to the pipe's full flow
capacity. In these cases, the downstream depth is taken as the greater of the actual downstream hydraulic
grade or the free discharge tailwater elevation. The free discharge tailwater depth is commonly
approximated as halfway between the crown of the pipe and the pipe's critical depth (in accordance with the
U.S. Federal Highway Administration's HDS-5).
Starting from the tailwater elevation, the pipe's full flow friction slope is used to determine the hydraulic
grade at the upstream end of the profile.
Excess Capacity Profiles
Excess capacity profiles occur when the full flow capacity of the pipe is greater than the actual flow in the
pipe. For these profiles, there are three basic tailwater conditions:
Case 1 - Hydraulic grade downstream less than or equal to normal depth.
Case 2 - Hydraulic grade downstream greater than normal depth, and less than or equal to pipe crown.
Case 3 - Hydraulic grade downstream greater than or equal to pipe crown.

Appendix B – SewerCAD Theory

257

Excess Capacity Profile, Case 1 (Hydraulic Grade <= Normal Depth):
If the downstream depth in the pipe is at or below the pipe’s normal depth, normal depth is assumed for the
pipe’s entire length.

Excess Capacity Profile, Case 1

Excess Capacity Profile, Case 2 (Normal Depth < Hydraulic Grade <= Pipe Crown)
When the hydraulic grade is above the pipe’s normal depth but below the top of the pipe, a friction slope of
zero is assumed until it either intersects the pipe’s normal depth or reaches the end of the pipe.

Excess Capacity Profile, Case 2

Excess Capacity Profile, Case 3 (Hydraulic Grade >= Pipe Crown)
If the hydraulic grade is above the pipe crown, the hydraulic grade continues upstream following the pipe’s
full flow friction slope. This slope will continue until it either intersects the pipe crown or reaches the end
of the pipe.
If the full friction slope intersects the crown of the pipe, the profile will continue with a Case 2
profile analysis.

258

Appendix B – SewerCAD Theory
Excess Capacity Profile, Case 3

Composite Excess Capacity Profiles
An excess capacity profile may actually be a composite of two more simple profiles. Consider the case
below, where the tailwater is above the crown of the pipe. In this case, the profile begins as a Case 3
profile. Where the full flow friction slope intersects the crown of the pipe, the profile changes to a Case 2
profile, following a flat slope until it reaches normal depth. Where normal depth is intersected, a Case 1
profile begins, extending all the way to the upstream end of the pipe.

Composite Excess Capacity Profile

B .4 Junction Headlosses and Minor Losses
B.4.1

Junction Headlosses
Structure Headloss
When water flows through a junction structure, there are headlosses associated with mixing, change of
direction, and so forth. This section deals with the computation of these losses based on the following
popular methods:


Absolute



Standard



HEC-22 Energy



AASHTO



Generic

Appendix B – SewerCAD Theory

259

Structure headlosses are used to determine the hydraulic grade to use as the tailwater condition for
upstream pipes during the backwater analysis. With the exception of the HEC-22 Energy method, the
headloss through the structure is assumed to be the same for each incoming pipe.

Headloss - Absolute Method
The absolute method is the simplest of the headloss methods. The structure headloss becomes an editable
value, which is then used during calculations. No computations relating to velocity, confluence angle, or
other factors are needed.

Headloss - Standard Method
The standard method calculates structure headloss based on the exit pipe’s velocity. The exit velocity head
is multiplied by a user-entered coefficient to determine the loss:

hs = K ⋅

Vo2
2g

Where:

hS =

Structure headloss (ft, m)

VO =

Exit pipe velocity (ft/s, m/s)

g =

Gravitational acceleration constant (ft/s2, m/s2)

K = Headloss coefficient (unitless)
For suggested coefficient values for various structure configurations, see the Typical Headloss Coefficient
table at the end of this chapter.

Headloss - Generic Method
The generic method computes the structure headloss by multiplying the velocity head of the exit pipe by
the user-entered downstream coefficient and then subtracting the velocity head of the governing upstream
pipe multiplied by the user-entered upstream coefficient.

hs = K0 ⋅

Where:

Vo2
V2
− K1 ⋅ 1
2g
2g
hS =

Structure headloss (ft, m)

VO =

Exit pipe velocity (ft/s, m/s)

KO =

Downstream coefficient (unitless)

V1 =

Governing upstream pipe velocity (ft/s, m/s)

K1 =

Upstream coefficient (unitless)

g = Gravitational acceleration constant (ft/s2, m/s2)
If there are multiple upstream pipes entering the junction then the program must choose one of the pipes to
use in the calculation. The pipe that is chosen is considered the governing upstream pipe. The governing
upstream pipe is selected based on one of the following methodologies:


The upstream pipe with the maximum flow times velocity



The upstream pipe with the maximum velocity head

• The upstream pipe with the minimum bend angle
The default method for selecting the governing upstream pipe is to choose the pipe with the maximum flow
times velocity. However, the user can select one of the other options through the generic structure loss
options.

260

Appendix B – SewerCAD Theory

Headloss-HEC-22 Energy Method
Similar to the standard method, the HEC-22 Energy method (from the FHWA’s Urban Drainage Design
Manual, Hydraulic Engineering Circular No. 22) correlates structure headloss to the velocity head in the
outlet pipe using a coefficient. Experimental studies have determined that this coefficient can be
approximated by:

K = K o CD C dC Q Cp CB
Where:

K =

Adjusted headloss coefficient

KO =

Initial headloss coefficient based on relative junction size

CD =

Correction factor for the pipe diameter

Cd =

Correction factor for flow depth

CQ =

Correction for relative flow

CP =

Correction for plunging flow

CB =

Correction factor for benching

Special Assumptions
The HEC-22 Energy method documentation is written with a limited range of applicability. Many of the
equations are written on the basis of pipe diameter, structure diameter, and so on. Since StormCAD and
SewerCAD offer non-circular pipes and non-circular structures, this creates the need for some
interpretation of the term "diameter."
In some cases, the intent of the methodology is to compare the size of one pipe to another pipe, or to the
size of a structure. In these cases an equivalent diameter is used, which is computed from the full area of
the pipe or structure. Equivalent diameter is the diameter of a circle with the area equal to the area of the
examined pipe or structure.
In other cases, the intent of the methodology is to compare depths within the structure. For these cases, the
rise (height) of the pipes is used in place of "diameter."
Pressure Flow, Free Surface Flow, and Transitional Flow
Throughout the documentation for HEC-22 Energy losses, you will see references to "pressure flow", "free
surface flow", and "transitional flow".
Pressure flow (submerged flow) is assumed to be any condition for which the depth of water above the
outlet pipe invert is greater than 3.2 times the height of the outlet pipe.
Free surface flow (unsubmerged flow) is assumed to be any condition for which the depth of water above
the outlet pipe invert is less than the height of the pipe.
Transitional flow is any condition between pressure flow and free surface flow.
Initial Headloss Coefficient
The initial headloss coefficient, which is based on relative junction size, is calculated as:

 b
K o = 0.1
 De
Where:


 b
(1 − sin θ ) + 1.4

D

 e






0.15

sin θ

θ =

Deflection angle between inflow and outflow pipes

b =

Equivalent diameter of the structure (m, ft)

De =

Equivalent diameter of the outlet pipe (m, ft)

Appendix B – SewerCAD Theory

261

The angle used in this equation is a deflection angle, so a straight run has a deflection angle of
180°. The bend angle in this case is 0°.
Correction for Pipe Diameter
The correction factor due to differences in pipe size is calculated only for pressure flow situations. For
non-pressure situations, a value of 1.0 is used.

D
C D =  o
 Di

3



 for pressure flow; CD = 1.0 for non-pressure flow

Where:

DO =

Outlet pipe rise (m, ft)

Di =

Inflow pipe rise (m, ft)

Correction for Flow Depth
The correction factor for flow depth is used only in cases of free surface flow or transitional flow. For
pressure flow, a value of 1.0 is used.
0.6

d
C d =  aho
 De



 for pressure flow; Cd = 1.0 for pressure flow

Where

daho

= Water depth in the structure (m, ft)

De =

Outlet pipe rise (m, ft)

Correction for Relative Flow
The correction factor for relative flow is calculated only when the invert elevation for the pipe in question
is approximately equal to the invert elevation of the outlet pipe and at least one other pipe. Otherwise, a
value of 1.0 is used.

 Q
C Q = (1 − 2 sin θ)1 − i
 Qo
Where:

θ
Qi

Qo






0.75

+1

=

Deflection angle between inflow and outflow pipes

=

Flow in the inflow pipe (m³/s, cfs)

=

Flow in the outflow pipe (m³/s, cfs)

The term "approximately equal" is quite a vague definition for when to use relative flow
corrections. StormCAD and SewerCAD enable you to change the tolerance for "approximately
equal" elevations so that you can use your judgment to fine-tune the HEC-22 methodology.
Correction for Plunging Flow
The correction factor for plunging flow accounts for the effect that flow plunging into a junction from
another inflow pipe has on the inflow pipe for which the headloss is calculated. It is calculated only when
vertical distance from the invert of the plunge pipe to the center of the outflow pipe is greater than the
depth in the structure relative to the outlet pipe invert. Otherwise a value of 1.0 is used.

262

Appendix B – SewerCAD Theory

 h
C p = 1 + 0.2
 Do
Where:

 h − d aho

 D
o







h =

Vertical distance from invert of the plunge pipe to the center of the outflow

De =

Outflow pipe rise (m, ft)

daho

=

pipe (m, ft)
Water depth in the junction relative to the outflow pipe invert (m, ft)

Correction for Benching
The correction factor for structure benching is similar to the shaping correction factor used in the AASHTO
structure loss method. The correction accounts for smoother transitions from the inflow pipe to the outflow
pipe based on the presence (or lack) of shaping in the bottom of the structure.
The following figure represents the four types of benching:

Types of Benching

By default, the program uses the values documented in HEC-22 (and presented in the following table) for
pressure and free surface flow, but the user can change these values. For transitional flow, the program
interpolates from the table linearly, based on the actual ratio of depth in the access hole to the height of the
outflow pipe.

Appendix B – SewerCAD Theory

263

Bench Type

Correction Factor, CB
Pressure *

Free Surface
**

Flat Floor

1.00

1.00

Depressed Floor

1.00

1.00

Half Bench

0.95

0.15

Full Bench

0.75

0.07

* pressure flow, daho / De > 3.2
** free surface flow, daho / De < 1.0
(daho is the water depth in the structure above the outlet pipe invert and DO is the outlet pipe diameter. )

Headloss-AASHTO Method
Headloss - AASHTO Method
The AASHTO method (as defined in the AASHTO Model Drainage Manual) for structure headloss is
based on power-loss methodologies. This method can be summarized by the following equation:

h s = (h c + h b + h e ) ⋅ C n ⋅ C s
Where:

hS =

Structure headloss (m, ft)

hC =

Contraction loss (m, ft)

hb =

Bend loss (m, ft)

he =

Expansion loss (m, ft)

Cn =

Correction factor for non-piped flow (unitless)

CS =

Correction factor for shaping (unitless).

AASHTO Contraction Loss
The contraction loss is due to flow transitioning from large-area, low-velocity flow to small-area, highvelocity flow, such as flow exiting a structure and entering a downstream pipe. This loss is calculated
based on the exit pipe’s velocity and a contraction coefficient, as follows:

hc = Kc

Where:

Vo2
2g
hc =

Contraction loss (m, ft)

Kc =

Contraction coefficient (unitless)

VO =

Exit pipe velocity (m/s, ft/s)

g = Gravitational acceleration constant (m/s², ft/s²)
The contraction coefficient defaults to the AASHTO documented value of 0.25, but can be changed by the
user.

264

Appendix B – SewerCAD Theory

AASHTO Bend Loss

hb =

 (1 − K i )Qi Vi 2 
Vo2
−∑

2g
Qo
2g 


Where:

hb = Bend loss (m, ft)
VO = Outflow pipe velocity (m/s, ft/s)
QO =

Outflow pipe velocity (m/s, ft/s)

Vi =

Inflow pipe velocity (m/s, ft/s)

Qi =

Inflow pipe flow (m³/s, cfs)

g =

Gravitational acceleration constant (m/s², ft/s²)

Ki =

Bend factor

The previous equation is a generalized version of the equation as it appears in the AASHTO
manual.
The program automatically computes a bend factor based on the angles at which the pipes come together.
The program’s default bend factors are based on Figure 13-12 of the AASHTO manual, but these values, as
with other AASHTO coefficients and corrections, can be changed by the user.
AASHTO Bend Loss Original Equation
The structure bend loss is computed for each incoming pipe using the following equation from the
AASHTO manual. Losses are computed for each incoming pipe, and the greatest value is used.
2

h b = Ki ⋅
Where:

V0
2g

hb =

Bend loss (m, ft)

Ki =

Bend loss coefficient (unitless)

Vo =

Incoming pipe’s velocity (m/s, ft/s)

g = Gravitational acceleration constant (m/s², ft/s²)
The AASHTO manual also documents another bend loss method shown in the following equation. The
authors of the AASHTO manual agree that either equation is acceptable. Because of the following
equation’s tendency to compute negative bend losses in certain cases, we decided to use the above equation
exclusively within this program.

Hi =
2

Q 4 V42 − Q 1 V12 − Q 2 V22 + KQ q V12
2gQ 4

Appendix B – SewerCAD Theory

265

AASHTO Expansion Loss
Expansion losses are encountered when small-area, high-velocity flow meets a large-area, low-velocity
flow, such as a pipe discharging into a structure. To compute this loss, the following equation is used:

he = K e ⋅
Where:

Vs2
2g
he =

Expansion loss (m, ft)

Ke =

Expansion coefficient (unitless)

Vs =

Most significant incoming pipe’s velocity (m/s, ft/s)

g = Gravitational acceleration constant (m/s², ft/s²)
The most significant pipe is the pipe that has the greatest product of velocity and discharge, omitting any
pipes that have a discharge less than 10% of the structure’s outflow. The expansion coefficient defaults to
the AASHTO documented value of 0.35, but can be changed by the user.
AASHTO Correction For Non-Piped Flow
If non-piped flow accounts for 10% or more of the total structure outflow, a correction factor is applied to
the total loss. By default, this value is a 30% increase in headloss (a factor of 1.3) as documented in the
AASHTO manual, but can be changed by the user.
AASHTO Correction for Shaping
If the bottom of the structure is shaped to facilitate smoother transitions from inflow pipes to the discharge
pipe, a correction factor can be applied to the total loss. By default, this value is a 50% reduction (a factor
of 0.5) as documented in the AASHTO manual, but can be changed by the user.

266

B.4.2

Appendix B – SewerCAD Theory

Minor Losses
Minor losses in pressure pipes are caused by localized areas of increased turbulence that create a drop in
the energy and hydraulic grades at that point in the system. The magnitude of these losses is dependent
primarily upon the shape of the fitting, which directly affects the flow lines in the pipe.
The equation most commonly used for determining the loss in a fitting, valve, meter, or other localized
component is:

hm = K

Where:

V2
2g
hm =

Loss due to the minor loss element (m, ft)

V =

Velocity (m/s, ft/s)

g =

Gravitational acceleration constant (m/s2, ft/s2)

K =

Loss coefficient for the specific fitting

Typical values for the fitting loss coefficient are included in the Fittings Table at the end of this chapter.
Generally speaking, more gradual transitions create smoother flow lines and smaller headlosses. For
example, the figure below shows the effects of a radius on typical pipe entrance flow lines.

Flow Lines at Entrance

Fitting Loss Coefficients
For similar fittings, the K-value is highly dependent on things such as bend radius and contraction ratios.

Appendix B – SewerCAD Theory

267
Typical Fitting K Coefficients

B .5 Pumping Stations and Pressure Sewers
B.5.1

Pump Theory
Pumps are an integral part of many pressure systems. Pumps add energy, or head gains, to the flow to
counteract headlosses and hydraulic grade differentials within the system.
A pump is defined by its characteristic curve, which relates the pump head, or the head added to the
system, to the flow rate. This curve is indicative of the ability of the pump to add head at different flow
rates. To model behavior of the pump system, additional information is needed to ascertain the actual point
at which the pump will be operating.
The system operating point is based on the point at which the pump curve crosses the system curve
representing the static lift and headlosses due to friction and minor losses. When these curves are
superimposed, the operating point can easily be found. This is shown in the figure below.

268

Appendix B – SewerCAD Theory
System Operating Point

As water surface elevations and demands throughout the system change, the static head (Hs) and
headlosses (HL) vary. This changes the location of the system curve, while the pump characteristic curve
remains constant. These shifts in the system curve result in a shifting operating point over time.
Variable Speed Pumps
A pump’s characteristic curve is fixed for a given motor speed and impeller diameter, but can be
determined for any speed and any diameter by applying the affinity laws. For variable speed pumps, these
affinity laws are presented as:

Q1
n
= 1
Q2 n2
Where:

and

h1  n1 

=
h 2  n 2 

2

Q =

Pump flowrate (m3/s, cfs)

h =

Pump head (m, ft)

n =

Pump speed (rpm)
Effect of Relative Speed on Pump Curve

Appendix B – SewerCAD Theory

269

Constant Horsepower Pumps
During preliminary studies, the exact characteristics of the constant horsepower pump may not be known.
In these cases, the assumption is often made that the pump is adding energy to the water at a constant rate.
Based on power-head-flowrate relationships for pumps, the operating point of the pump can then be
determined. Although this assumption is useful for some applications, a constant horsepower pump should
only be used for preliminary studies.

B.5.2

Pump Type
This software currently models six different types of pumps:


Design Point (One-Point) - A pump can be defined by a single design point (Hd @ Qd). From this
point, the curve's interception with the head and discharge axes is computed as Ho = 1.33•Hd and Qo =
2.00•Qd. This type of pump is also useful for preliminary designs, but should not be used for final
analysis.



Standard (Three-Point) - This pump curve is defined by three points - the shutoff head (pump head at
zero discharge), the design point (as with the single-point pump), and the maximum operating point
(the highest discharge at which the pump performs predictably).



Standard Extended - The same as the standard three-point pump, but with an extended point at the
zero pump head point. This is automatically calculated by the program.



Custom Extended - The custom extended pump is similar to the standard extended pump, but allows
you to enter the discharge at zero pump head.



Multiple Point - This option allows you to define a custom rating curve for a pump. The pump curve
is defined by entering points for discharge rates at various heads. Since the general pump equation,
shown below, is used to simulate the pump during the network computations, the user-defined pump
curve points are used to solve for coefficients in the general pump equation:

Y = A − (B × Q C )

Y = A − (B × Q C )
Where:

Y

=

Head (m, ft)

Q

=

Discharge (m3/s, cfs)

A, B, C =
Pump curve coefficients
The Levenberg-Marquardt Method is used to solve for A, B and C based on the given multiple-point rating
curve.


Constant Power - These pumps may be useful for preliminary designs and estimating pump size, but
should not be used for any analysis for which more accurate results are desired.
Whenever possible, avoid using constant power or design point pumps. They are often enticing
because they require less work on behalf of the engineer, but they are much less accurate than a
pump curve based on several representative points.
It is not necessary to place a check valve on the pipe immediately downstream of a pump,
because pumps have built in check valves that prevent reverse flow.

270

B.5.3

Appendix B – SewerCAD Theory

Conservation of Mass and Energy
Conservation of Mass
At any node in a system containing incompressible fluid, the total volumetric or mass flows in must equal
the flows out, less the change in storage. Separating these into flows from connecting pipes, demands, and
storage, we obtain:

∑ QIN ∆t = ∑ Q OUT ∆t + ∆VS
Where: QIN

=

Total flow into the node (m3/s, cfs)

QOUT =

Total demand at the node (m3/s, cfs)

∆VS

=

Change in storage volume (m3, ft3)

∆t

=

Change in time (s)

Conservation of Energy
The conservation of energy principle states that the headlosses through the system must balance at each
point. For pressure networks, this means that the total headloss between any two nodes in the system must
be the same regardless of what path is taken between the two points. The headloss must be sign consistent
with the assumed flow direction (i.e. gain head when proceeding opposite the flow and lose head when
proceeding with the flow).

Conservation of Energy

The same basic principle can be applied to any path between two points. As shown in the figure above, the
combined headloss around a loop must equal zero in order to achieve the same hydraulic grade as at the
beginning.

B.5.4

The Gradient Algorithm
The gradient algorithm for the solution of pipe networks is formulated upon the full set of system equations
that model both heads and flows. Since both continuity and energy are balanced and solved with each
iteration, the method is theoretically guaranteed to deliver the same level of accuracy observed and
expected in other well known algorithms such as the Simultaneous Path Adjustment Method (Fowler) and
the Linear Theory Method (Wood).
In addition, there are a number of other advantages that this method has over other algorithms for the
solution of pipe network systems:


The method can directly solve both looped and partly branched networks. This gives it a
computational advantage over some loop-based algorithms, such as Simultaneous Path, which require
the reformulation of the network into equivalent looped networks or pseudo-loops.



Using the method avoids the post-computation step of loop and path definition, which adds
significantly to the overhead of system computation.

Appendix B – SewerCAD Theory


271

The method is not numerically unstable when the system becomes disconnected by check valves,
pressure regulating valves, or modeler’s error. The loop and path methods fail in these situations.



The structure of the generated system of equations allows the use of extremely fast and reliable sparse
matrix solvers.
The derivation of the Gradient Algorithm starts with two matrices and ends as a working system of
equations.

B.5.5

Derivation of the Gradient Algorithm
Given a network defined by N unknown head nodes, P links of unknown flow, and B boundary or fixed
head nodes, the network topology can be expressed in two incidence matrices:

A 12 = A 21T

(P x N) Unknown head nodes incidence matrix

A 10 = A 01T

(P x B) Fixed head nodes incidence matrix

and

The following convention is used to assign matrix values:

A 12 (i, j) =

1, 0, or -1

if flow of pipe i enters, is not connected, or leaves node j,
respectively.

Assigned nodal demands are given by:

q T = [q1, q 2 ,..., qN ]

(1 x N) nodal demand vector

Assigned boundary nodal heads are given by:

H f T = [H f 1, H f 2 ,...H f B ]

(1 x B) fixed nodal head vector

The headloss or gain transform is expressed in the matrix:

F T (Q) = [f1, f 2 ,..., fP ]

(1 x P) non-linear laws expressing headlosses in links

fi = fi (Qi )
These matrix elements that define known or iterative network state can be used to compute the final steadystate network represented by the matrix quantities for unknown flow and unknown nodal head.
Unknown link flow quantities are defined by:

Q T = [Q1, Q 2 ,..., Q P ]
Unknown nodal heads are defined by:

(1 x P) unknown link flow rate vector

272

Appendix B – SewerCAD Theory

HT = [H1,H2 ,..., HN ]

(1 x N) unknown nodal head vector

These topologic and quantity matrices can be formulated into the generalized matrix expression using the
laws of energy and mass conservation:

A 12H + F(Q) = − A 10H f
A 12 Q = q
A second diagonal matrix that implements the vectorized head change coefficients is introduced. It is
generalized for Hazen-Williams friction losses in this case:

A 11

R Q n1 −1
 1 1

R2 Q2

=








...


...

n −1
R P QP P 

n2 −1

This yields the full expression of the network response in matrix form:

 A 11 A 12  Q − A 10H f 
=



0  H  
q

 A 21
To solve the system of non-linear equations, the Newton-Raphson iterative scheme can be obtained by
differentiating both sides of the equation with respect to Q and H to get:

NA 11 A 12  dQ − dE 
=


0   dH   dq 
 A 21
with

n1



n2


N=


...


nP 

The final recursive form of the Newton-Raphson algorithm can now be derived after matrix inversion and
various algebraic manipulations and substitutions (not presented here). The working system of equations
for each solution iteration, k, is given by:
−1

{

−1

}

H k +1 = −(A 21 N −1 A11 A12 ) −1 A 21 N −1 (Q k + A 11 A 10 H f ) + (q − A 21Q k )
−1

Q k +1 = (1 − N −1 )Q k − N −1 A 11 (A12 H k +1 + A10 H f )

Appendix B – SewerCAD Theory

273

The solution for each unknown nodal head for each time iteration is computationally intensive. This high
speed solution utilizes a highly optimized sparse matrix solver that is specifically tailored to the structure of
this matrix system of equations.
Sources:
Todini, E. and S. Pilati, "A gradient Algorithm for the Analysis of Pipe Networks", Computer Applications
in Water Supply, Vol. 1 - Systems Analysis and Simulation, ed. By Bryan Coulbeck and Chun-Hou Orr,
Research Studies Press LTD, Letchworth, Hertfordshire, England.

B.5.6

The Linear System Equation Solver
The Conjugate Gradient method is one method that, in theory, converges to an exact solution in a limited
number of steps. The Gradient working equation can be expressed for the pressure network system of
equations as:

Ax = b
where:

x = Hk + 1

{

−1

}

b = − A 21 N −1 (Q k + A 11 A 10 H f ) + (q − A 21Q k )
The structure of the system matrix A at the point of solution is:

A = A 21(NA 11 ) −1 A 12 = A 21DA 12
and it can be seen that the nature of the topological matrix components yield a total working matrix A that
is:


Symmetric



Positive definite

• Stieltjes type
Because of the symmetry, the number of non-zero elements to be retained in the matrix equals the number
of nodes plus the number of links. This results in a low density, highly sparse matrix form. It follows that
an iterative solution scheme would be preferred over direct matrix inversion, in order to avoid matrix fill-in
which serves to increase the computational effort.
Because the system is symmetric and positive definite, a Cholesky factorization can be performed to give:

A = LLT
where L is lower triangular with positive diagonal elements. Making the Cholesky factorization allows the
system to be solved in two steps:

y = L−1b
x = (LT ) −1 y

274

Appendix B – SewerCAD Theory

The use of this approach over more general sparse matrix solvers that implement traditional Gaussian
elimination methods without consideration to matrix symmetry is preferred, since performance gains are
considerable. The algorithm utilized in this software solves the system of equations using a variant of
Cholesky’s method which has been optimized to reduce fill-in of the factorization matrix, thus minimizing
storage and reducing overall computational effort.

B .6 Extended Period Simulations
B.6.1

Extended Period Simulations Overview
The Extended Period Simulation (EPS) models how a sewer network will behave over time. This type of
analysis allows the user to model wet wells filling and draining, how pumps toggle on and off, and how
pressures, hydraulic grades, and flow rates change throughout the system in response to varying loading
conditions and in response to automatic control strategies formulated by the modeler. In SewerCAD the
algorithm proceeds in a general downstream direction proceeding towards the outfall and occurs in the
following steps:
1.

The analysis begins in the gravity portion of the network. All hydrographs are generated entering
into the gravity system and successively routed and summed as the flows approach the bounding
wet well. Ultimately, the total inflow hydrograph to the wet well is determined.

2.

Knowing the inflow to the wet well, the pressure calculations for the force main system bounded
by the wet well are performed. In addition to flow velocities and pressures, the levels in the wet
well are determined over time.

3.

SewerCAD then returns to the gravity portion of the network discussed in step 1. The hydraulics
and HGL profiles are calculated throughout the gravity system for each time step using the
known level of the wet well as the boundary condition for the backwater analysis.
The process then repeats, continuing to the systems downstream of the pressure network until an outlet is
reached.

B.6.2

Routing Overview
As a hydrograph flows through a conduit it undergoes changes in shape and temporal distribution caused
by translation and storage effects.
SewerCAD uses two methods to determine the shape and distribution of a hydrograph routed through a
gravity pipe.

B.6.3



Convex Routing



Weighted Translation Routing

Convex Routing
The underlying assumption of the convex routing method is that the routed outflow for a time step is based
on the inflow and outflow for the previous time step. Each outflow ordinate is calculated as:

Ot + ∆t = cI t + (1 − c )Ot
Where:

O t + Dt

=

Outflow at time t + Dt

t
Dt

=
=

Current time (s, min)
Hydrologic time step (s, min)

Appendix B – SewerCAD Theory

275

c

=

Convex routing coefficient

It

=

Inflow at time t (l/s, gpm)

Ot
=
Outflow at time t (l/s, gpm)
The convex routing coefficient is essentially a ratio of the hydrologic time step and representative flow
travel time through the pipe and is calculated as follows:

c = ∆t

V ∆t
=
L tt

Where:

Dt

=

Hydrologic time step (s)

tt

=

Travel time (s)

V

=

Velocity established for representative flow. (m/s, ft/s)

L
=
Length of pipe (m, ft)
The velocity used to calculate the coefficient is either the normal velocity or full flow velocity generated
for a user-specified percentage of the peak of the inflow hydrograph. In other words, if the percentage of
the peak flow is greater than the capacity of the pipe then the full-flow velocity is used. If the percentage
of the peak flow is less than the capacity the flow velocity for normal depth is used.
You can specify the percentage of the peak flow, which is used to calculate the Convex Routing c
coefficient for each pipe, by clicking the Go button and then clicking the Options button. Then
click the Convex tab of the Calculation Options dialog. The values typically range between 50%
and 75%.
The higher the percentage of flow the faster the velocity used to calculate the convex routing coefficient,
hence the closer the routed hydrograph will be to a pure translation of the inflow hydrograph.
The user-specified percentage can be modified in the calculation options. A typical value is around 75 %
but can be modified for oddly shaped hydrographs with sharp uncharacteristic peaks or for calibration
purposes.

B.6.4

Weighted Translation Routing
The Convex Routing method is only valid when the Convex Routing coefficient, c is less than 1 or when
the hydrologic time step is less than the calculated travel time. In certain cases where the travel time
exceeds the hydrologic time step, SewerCAD automatically uses an alternate method of routing.
Each ordinate of the outflow hydrograph is derived from a weighted average of the ordinates for the current
and previous time steps of the inflow hydrograph. The weights are calculated based on the Convex
Routing coefficient.
Each ordinate of the outflow hydrograph is calculated as follows:

1
 1
Ot = I t − ∆t + 1 −  I t
c
 c
Where

Ot

=

Outflow at current time step (l/s, gpm)

c
I t - Dt

=
=

Convex Routing coefficient
Inflow at previous time step (l/s, gpm)

It

=

Inflow at current time step (l/s, gpm)

276

B.6.5

Appendix B – SewerCAD Theory

Hydrologic and Hydraulic Time Steps
SewerCAD uses two distinct time steps when running an Extended Period Simulation.


Hydrologic Time Step - This time step is used to calculate the routed hydrographs and represents the
time increment of all hydrographs generated during the analysis. The hydrologic time step is also used
as the calculation increment for the pressure calculations.



Hydraulic Time Step - This time step represents how often the hydraulic calculations are performed.
Flows are interpolated off the previously generated hydrographs using the hydraulic time step and are
used to perform the gradually varied flow analyses for that time step.
The hydrologic time step should be less than or equal to the hydraulic time step. The hydraulic time step
should be a multiple of the hydrologic time step.
The Hydrologic and Hydraulic Time Steps can be modified in the Extended Period Simulation
section of the Scenario / Go dialog.

B .7 Transitioning Between Gravity and Pressure Networks
B.7.1

Overview
This section describes the major distinctions between gravity pipes and force mains in SewerCAD. It also
describes how flow and the hydraulic grade transition between force mains and gravity pipes and vice
versa.

B.7.2

Identifying Gravity Pipes and Force Mains
Superficially, SewerCAD depicts a force main (pressure pipe) as a single line, and a gravity pipe as two
parallel lines.
The difference can also be recognized by the pipe’s context in the network. The pipes in a gravity system
must all converge on a single termination point in a classic tree structure. Multiple pipes can enter into a
single gravity node, but only one may exit. The gravity subnetwork can either terminate on a wet well, or
an outlet.
The force mains can be much more complex with loops and multiple outlet points. The pressure
subnetwork can terminate on an outlet, a manhole, or a junction chamber.

B.7.3

Direction of Flow in Gravity and Pressure Systems
In gravity pipes flow will always travel towards the termination point of the gravity network. Once the
gravity pipes are drawn in the network and connected to an outlet or wet well, all the pipes will orient
themselves such that downstream points toward the termination point.
Pressure systems are usually designed such that flow will travel from the wet well to an outfall point at
either an outlet or a gravity system. If the elevation is too high at that point, SewerCAD will allow flow to
travel backwards from the gravity system to the pressure network. There are no programmatic limitations
as to the direction of flow in the force main system.

Appendix B – SewerCAD Theory

B.7.4

277

Transitioning From Gravity Pipes to Force Mains
Overview
The only way to transition between a gravity pipe and a force main in SewerCAD is through an
intermediate wet well. This establishes a boundary condition for both the connecting systems. During a
Steady State analysis the wet well level can be calculated based on generating the required HGL for the
outflow to either match or exceed the inflow, or the wet well level can be fixed to a user-specified level.
During an Extended Period Simulation the wet well level is determined for a time step by calculating the
change in storage over time.
The inflow into the wet well is determined by summing all loads flowing to that wet well.

Hydraulic (HGL) Transition from Gravity to Pressure Network
Gravity hydraulic calculations upstream of a wet well are based on the wet well hydraulic grade, just as
they are for standard calculations within gravity systems.
During a Steady State analysis there is a difference, however, in determining the hydraulic grade within the
wet well itself. The wet well level may be set by the user to either be fixed or not fixed.
Fixed Wet Well Level during Steady State Analysis
If the wet well level is fixed, the wet well’s starting hydraulic grade is used for pressure calculations. No
adjustments are made, and this grade is used as the tailwater grade for the upstream gravity systems.
Non-Fixed Wet Well Level during Steady State Analysis
If the wet well level is not fixed, the pressure calculations will attempt to balance the wet well level such
that the total flow out of the wet well is equal to or greater than the total flow into the wet well.
The wet well’s starting grade is used for the first iteration. If the calculated flows out of each wet well are
greater than or equal to each wet well’s incoming flow, the iterations stop there. If not, the wet well levels
are increased by the increment specified in the calculation options, and the pressure subnetwork is
recalculated. When the wet well level is increased, it changes the static heads and increases the discharge
for connected pumps, and may also trigger additional pumps to turn on.
This process continues until the level in each non-fixed wet well either meets the flow criteria, or is
prevented by rising to the maximum elevation of the wet well.
Wet Well Level During Extended Period Simulations
During an Extended Period Simulation the fixed wet well level options are not available. The wet well
level for a time step is actually determined by the change in storage due to inflows and outflows over a
single time step.

Hydrologic (Flow) Transition from Gravity to Pressure Network
The hydrologic transition from a gravity system into a pressure system is quite simple. Gravity loads
upstream from the wet well are accumulated and combined with the wet well’s local load to determine the
total load entering the pressure system at that location. This can be imagined as the total load "dumping
into" the wet well.

B.7.5

Transitioning From Force Mains to Gravity Elements
Overview
Force mains can empty directly into the gravity system via a manhole, or a junction chamber, or they can
terminate at an outlet. During a Steady State analysis the flow entering the gravity system can either be

278

Appendix B – SewerCAD Theory

only the specified sanitary and wet weather loads, or the load generated based on the pumps, the wet well
level and the hydraulic characteristics of the force main system.
During an Extended Period Simulation flows to the gravity system are solely determined based on the
hydraulic characteristics of the force main system.
If the force main empties into an outlet the HGL boundary is determined by the elevation of the user
specified-tailwater. The HGL boundary between the force main and gravity system is determined by the
elevation of the force main at the boundary point.

Hydraulic (HGL) Transition from Pressure to Gravity Network
If the force main empties into and outlet element, then the hydraulic grade will be the higher of the set
tailwater elevation or the crown of the pressure pipe.
The hydraulic grade at a manhole or a junction chamber downstream from a discharging force main is not
considered when performing pressure calculations. Instead, the boundary hydraulic grade is assumed to be
equal to the crown elevation of the discharge pipe.
For example, if a 150 mm pipe discharges at an invert elevation of 10.000 m, the hydraulic grade that is
used as the boundary condition for the pressure system is 10.150 m.
This assumption is absolutely valid and conservative when the hydraulic grade line in the gravity element is
below the crown of the pipe.
This is generally a valid assumption when the hydraulic grade line is above the crown of the pipe as the
head at the entrance of the gravity network is often insignificant compared to the friction losses incurred
through the force mains.

Hydrologic (Flow) Transition from Pressure to Gravity Network
The hydrologic transition from a pressure system into a gravity system during a Steady State analysis is
somewhat complicated, with different desired behaviors for different analysis purposes. If the model is
built for direct analysis of flows in the system, it is most likely that instantaneous pumped flows are
important, and the downstream gravity loads should include the pumped discharge from the pressure
system. If the analysis is for large-scale planning purposes, however, it is more likely that instantaneous
pumping rates are not as important. In these cases, the downstream gravity system should be analyzed
based on the total contributing population, area, or other factors for determining peak flows.
Hydrologic Transition from Pressure to Gravity During Steady State Analysis
Conserving Pumped Flow
When instantaneous pumped flows are a concern in the downstream gravity system, the calculation option
to conserve pumped flow should be used. This is found on the Pressure Hydraulics Options tab of the
Calculation Options dialog. When this option is used, the contributing load components from the pressure
system are ignored, and a load of type "Pumped" is added to the gravity system with the magnitude of the
flow in the discharging pressure pipe. If the flow in the pressure pipe is such that the gravity system would
be draining into the pressure system, no load is transferred to that gravity node.
Conserving Load Components
When instantaneous pumped flows are not a concern in the downstream gravity system, the calculation
option to conserve load components (not pumped flow) should be used. When conserving load
components, the total contributing components to the pressure system (population, area, and so forth) are
considered. The total contributing load is distributed to the downstream gravity systems proportionally to
the pressure pipe discharge rates. If the flow in a pressure pipe is such that the gravity system would be
draining into the pressure system, no load is transferred to that gravity node.

Appendix B – SewerCAD Theory

279

Comparison of Pressure Load Routing
Consider the system below with the following load equivalents:
300 people = 100 l/s
200 people = 70 l/s
100 people = 50 l/s

Network System

The total load population contributing to the load entering the pressure system is 300 people, equivalent to
a flow of 100 liters per second. The operating points of each pump are such that the discharges into the
downstream gravity systems are 200 liters per second and 400 liters per second. This is more than the rate
of flow entering the wet well.
When conserving pumped flow, the flows in each discharging force main are transferred directly to the
downstream gravity system, resulting in a pumped load of 200 l/s at O-1 and a pumped load of 400 l/s at O2.
When conserving load components, the 300 people contributing to the load at the wet well are split
proportionally to the downstream gravity systems (1/3 and 2/3). This results in a load of 100 people (50
l/s) at O-1, and 200 people (70 l/s) at O-2.
The differences can also be seen for the following system, with the same load equivalents as above.

280

Appendix B – SewerCAD Theory
Network System

When conserving pumped loads, the downstream gravity load is computed as:
400 l/s + 100 people = 400 l/s + 50 l/s = 450 l/s
When conserving load components, the downstream gravity load is computed as:
200 people + 100 people = 300 people = 100 l/s
Note that for this piping configuration (one source of loading for the pressure system, one possible
discharge point for the pressure system), the downstream load will always be 100 l/s (300 people)
regardless of the actual pump operating point.
Hydrologic Transition from Pressure to Gravity During Extended Period Simulations
Since the wet well level will vary over time, based on the inflow and outflow, no distinction is made
between standard loads and pumped loads during an Extended Period Simulation. The loads will be
transferred through the force main system based on the hydraulic characteristics of the pumps and the
system headlosses.
If the elevation of the force main emptying into the gravity system is high enough that flow goes backward
from the gravity element during an Extended Period Simulation, the negative portion of the hydrograph
going through the gravity system at that point will be truncated. Only positive flows are analyzed in the
gravity system. Negative flows are assumed to be 0. (See the Hydraulic Transition from Pressure to
Gravity Network for more information)

B .8 Constraint Based Automatic Design
B.8.1

Gravity Pipes and Structures Design
This program allows you to automatically design gravity piping and structures. The design is flexible
enough to allow you to specify the elements to be designed, from a single pipe size to the entire system, or
anything in between.
The design algorithm adjusts invert elevations and the section size of the pipe to meet several constraints,
such as allowable ranges of slope, velocity and cover. In general, the design algorithm attempts to
minimize pipe size and excavation, which is typically the most expensive part of installing sewer piping
and structures.
Some of the other things that are considered include:


Pipe Matching



Offset Matching



Drop Structures

Appendix B – SewerCAD Theory

281

• Structure Sump Elevations
The designed pipe will be the smallest available section size from the Engineering Library that meets the
constraints and has a capacity greater than its discharge. In a situation where there are no pipe sizes with
adequate capacity, the largest available size will be used.

B.8.2

Part Full Design
Pipes are designed such that the capacity is greater than the calculated discharge. For standard designs, this
capacity is based on full pipe, normal depth - that is, the flow in the pipe when the depth is 100% of the
pipe rise.
With partially full design, the designed capacity of the pipe is for a design depth that is only a portion of the
pipe rise. In other words, a pipe that is designed for 50% full will be selected based on a depth of half of
the pipe's rise.
For example, consider a circular pipe with the following characteristics:
Slope = 0.01 m/m
Roughness n = 0.013
Required flow = 100 l/s
The following table presents several typical section sizes, with their capacities at various depths.

Flow Capacities
Circular Section
Size

100% Full

80% Full

50% Full

Nominal
Diameter

Depth
(mm)

Capacity
(l/s)

Depth
(mm)

Capacity
(l/s)

Depth
(mm)

Capacity
(l/s)

300 mm

300

101

240

99

150

50

375 mm

375

183

300

179

188

91

450 mm

450

297

360

291

225

149

Depending on the selected percent-full, the smallest available pipe could be for any of the bold values
above. Obviously, if the design percentage were something different, an even larger section may be
required.
Hydraulically, the capacity at a percentage of pipe rise is generally not equal to that percentage of the full
pipe capacity. As can be seen in the table above, 80%-full capacity does not equal 80% of the 100%-full
capacity.
For sections that are vertically symmetrical, 50% full is a special case where the wetted perimeter and area
are both half that of full flow. This means that the hydraulic radius and velocity are the same for half-full
and full flow, resulting in a highly special condition where the 50%-full capacity is actually equal to one
half of the 100%-full capacity.

B.8.3

Allow Multiple Sections
Situations may be encountered where the desired capacity cannot be met with a single pipe, due to a
limiting maximum section rise, a lack of larger available pipes, or other restrictions. For these situations,
the pipe can be designed with multiple barrels. All barrels will have the same physical characteristics.

282

Appendix B – SewerCAD Theory

Multiple barrels will only be used if the design cannot be met by a single available section size, and the
pipe allows multiple sections for design. In these cases, the design will increase the number of barrels and
attempt to find a section size that meets the capacity, continuing until the capacity is met or the maximum
number of barrels is reached.
For example, consider a circular pipe with the following characteristics:
Slope = 0.01 m/m
Roughness n = 0.013
Required flow = 750 l/s
Maximum Design Section Rise = 700 mm
Assume that the design is for 100% full capacity, allowing up to three barrels of the following section sizes:

Design with Multiple Sections
Circular
Section Size

1 Barrel

2 Barrels

3 Barrels

Nominal
Diameter

Capacity
(l/s)

Meets
Flow?

Capacity
(l/s)

Meets
Flow?

Capacity
(l/s)

Meets
Flow?

300 mm

101

No

202

No

203

No

375 mm

183

No

366

No

549

No

450 mm

297

No

595

No

892

Yes

525 mm

449

No

897

Yes

1346

Yes

600 mm

641

No

1281

Yes

1922

Yes

For these conditions, the selected design would use two 525 mm barrels - the smallest section size within
the least number of barrels to meet the capacity criteria.

B.8.4

Limit Section Size
There may be situations in design where it is desired to limit the size of the designed pipe. This may be
done to avoid conflicts with obstructions or other utilities, for example. For these situations, The program
enables you to limit the maximum section rise that will be selected. A smaller size will be used if possible.
If none of the available design sections have a small enough rise, the smallest one will be used.

B.8.5

Pipe Matching
When pipes meet at a structure, it is often desirable to have the pipes at approximately the same elevation.
To do this, the program allows you to design your pipes to match inverts or crowns. This means that when
the design is done (if a valid design was found), all of the designed pipes entering a structure will have the
same invert elevation or crown elevation.

B.8.6

Offset Matching
If an offset value is specified, it represents the desired drop across the structure. The design incorporates
this offset, resulting in upstream pipes that are higher than the downstream pipe by the specified offset.
Note that all designed upstream pipes will have the same invert or crown elevation.

Appendix B – SewerCAD Theory

283

For example, an offset of 0.1 meter could result in a downstream pipe with an invert of 100.0 meters, and
several upstream pipes with invert elevations at 100.1 meters.

B.8.7

Drop Structures
Drop structures are structures at which the incoming pipes are not all at the same elevation, nor do any of
them necessarily match the downstream pipe. Including these structures may help to reduce excavation,
since the entire upstream system does not need to be as deep.
The program will only use drop structures if you have chosen to allow them, and if a pipe’s maximum
slope constraint cannot be met. Otherwise, the upstream system will be designed as needed to maintain the
desired slope and velocity constraints, which may require significantly lower pipe elevations.

B.8.8

Structure Sump Elevations
The program can adjust structure sump elevations to account for the invert elevations of newly designed
pipes, and any desired additional sump depth.
For example, if a structure is to be adjusted with a sump depth of 0.5 meters and the lowest pipe invert is
100.0 meters, the structure sump elevation would be set to 99.5 meters.

B.8.9

Design Priorities
Unfortunately, it is not always possible to automate a design that meets all desired constraints. With this in
mind, there are certain priorities that are considered when the automated design is performed. These
priorities are in place to try to minimize the effect on existing portions of the system while providing
appropriate capacity in the designed pipes.
While this sequence does not go into complete detail regarding the design process, it does indicate the
general priorities for the automated design. The priorities, of course, only deal with elements that are being
designed. If a pipe has fixed inverts or is not to be designed at all, some or all of these criteria obviously do
not apply.
A Designed Pipe Should Fit within Adjacent Existing Structures
If a pipe connects to an existing structure, the pipe rise should be completely within the existing structure.
The only time this may be violated is if there are no available section sizes that would not violate that
condition (i.e., the existing structure height is so small that all available pipes have rises too big). In this
very unlikely condition, the smallest available section size will be selected, with the invert elevation placed
at the bottom of the structure.
A Designed Pipe Should Not Have a Crown Above an Adjacent Designed Structure
Where pipe inverts are fixed, it is possible that the required section size would cause the pipe crown to be
higher than the top elevation of an adjacent designed structure. If all available pipe section rises are greater
than the depth of the pipe invert, the smallest pipe size will be chosen.
This situation will only be encountered in situations where the structure's top elevation is set
equal to the ground elevation - otherwise, the structure will be designed with a higher top
elevation.

284

Appendix B – SewerCAD Theory
Crown above Adjacent Structure

Pipe Capacity Should Be Greater Than the Discharge
If the pipe is not limited by adjacent structures, the pipe should be sized such that the design capacity is
greater than the calculated discharge in the pipe. The design capacity may be based on one or more pipes,
flowing full or part-full, depending on user-set design options. If site restrictions or available section
limitations result in a situation where no sections meet the required capacity, the largest available size and
number of barrels will be chosen.
Downstream Pipes Should Be at Least as Large as Upstream Pipes
Designs typically avoid sizing downstream pipes smaller than upstream pipes, regardless of differing slope
and velocity requirements. One of the primary reasons for this is debris that passes through the upstream
pipe could become caught in the connecting structure, clogging the sewer.

Sizing of Pipes

Appendix B – SewerCAD Theory

285

Pipe Matching Criteria Downstream Should Be Met
Whenever possible, the designed pipe should have its downstream invert set such that the pipe meets the
matching criteria, such as matching inverts or crowns. Note that because of higher design priorities, such
as the pipe fitting within existing structures, the matching criteria may not always be met.
Minimum Cover Constraint Should Be Met
Pipe inverts should be set such that the upstream and downstream crowns of the pipe are below the ground
elevation by at least the amount of the minimum cover. Note that higher design priorities, such as existing
structure locations and matching criteria, may prevent the minimum cover constraint from being met.
Pipe Matching Criteria Upstream Should Be Met
The upstream invert of the designed pipe should be set to meet the matching criteria of the upstream
structure. Higher design priorities, such as minimum cover constraints, may result in a pipe that does not
match upstream as desired.
Maximum Slope Constraint Should Be Met
Wherever possible, the designed pipe should not exceed the desired maximum slope. In some situations,
elevation differences across the system may result in a case where a drop structure can be used to offset
pipes. This is used instead of a pipe that is too steep, or instead of upstream piping that would require
much more excavation. Note that the maximum slope constraint may be violated if higher priority design
considerations, such as existing structure location or pipe matching criteria, governs.
Other Constraints and Considerations
There are many degrees of freedom when designing a piping system. Several constraints that are not
mentioned above, such as minimum velocity constraints and minimum slope constraints, may also result in
adjustments to the designed pipe. Other constraints may be too limiting, such as maximum cover constraint
and maximum velocity, resulting in designed pipes that could violate too many other constraints.
This wide range of choices and priorities emphasizes the need for careful review of any automated design
by a professional. It is not always possible to meet every desired condition, so it is very much the
responsibility of the engineer to make final judgments and decisions regarding the best design for the client.

B.8.10

Automatic Design with Hydrograph and Pattern Loads
Automatic designs are run only during a Steady State analysis, which examines only a single instant in
time. There are some key behaviors attributed to time-based loads that you may wish to take into account
when designing the system.
As described in the Common Load Types section of the help, hydrographs can be applied as stead state
loads in four different ways (Peak, Average, Minimum, and Zero). If you have hydrograph loading applied
to the gravity model, the selected steady state loading option could have a dramatic effect on the ultimate
design. For example, when running a design, you may get larger pipes when the inflow loads are based on
the peak flows of the hydrographs vs. if they are based on the minimum flows of the hydrographs.
To access the Steady State Loading options, click the Go button. Then click the Options button.
Click the Steady State Loading tab in the Calculation Options dialog.
Pattern Loads generally consist of an average base load and a diurnal pattern. During a Steady State
Analysis, and hence the Design, the pattern is disregarded and the base load is used as the load.

286

B.8.11

Appendix B – SewerCAD Theory

Constraint Based Warning Messages
The calculated properties of the pipe such as flow velocity, slope, and cover are always being checked
against the design constraints regardless of the type of simulation being run.
During a design, you will get warning messages associated with a particular pipe if the algorithm could not
attain a solution where all the constraints are met.
If you are running a regular Steady State analysis or an Extended Period Simulation, however, and the
constraints are violated (i.e. a velocity in a pipe is higher than the maximum velocity constraint), then, like
in Design mode, a warning message will also be generated stating a violation as occurred.
These types of warning messages are generated based entirely on the on the user-specified design
constraints, and have no affect on the results or the analysis. These constraints are setup as either default
design constraints through the Analysis menu, or as local constraints through the element editor or the
Design Alternative. The local design constraints have precedence over the default design constraints.

B .9 Special Considerations
There are a few special considerations that should be realized when analyzing a sewer system. These are
conditions where special assumptions need to be made, or where calculations may seem counter-intuitive at
first glance. These considerations include:

B.9.1



Energy Discontinuity



Structure Energy Grade



Design Considerations

Energy Discontinuity
The program by default uses hydraulic grade as the basis for its hydraulic computations. Energy grade at
any given point is then computed by adding the velocity head to the hydraulic grade. Because of this
standard practice, energy discontinuities may occasionally occur, such as when pipe size decreases in the
downstream direction, or pipe slope increases.
If you wish the calculations to be based on the energy grade line you can modify the Haestad.ini file
located in the base Haestad directory. Find [SWRC] or [STMC] in the file depending on which product
you are using, and create a new line below the heading. In the new line enter in the following text typed
exactly as printed below.
StructureLossMode=EGL
Save and close the Haestad.ini file and reopen the program. To revert back to an HGL based analysis;
simply remove the line from the Haestad.ini file and save.
Flow discontinuities can also be responsible for energy discontinuities. Since a structure is analyzed based
on a different system time than a pipe, a direct comparison of energy grades is not reasonable.

B.9.2

Structure Energy Grade
The energy grade line (EGL) at the upstream side of a structure is computed based on the characteristics of
the structure and its upstream pipes. The reported EGL is generally reported as the lowest EGL of all nonplunging upstream pipes, based on normalized flow values. If there are no non-plunging pipes upstream,
the structure's upstream EGL is taken as the higher of the structure's downstream EGL and upstream
hydraulic grade line (HGL).
In situations where the structure's upstream EGL is lower than its downstream EGL or upstream HGL, the
highest value governs. This rare condition may indicate that the presumed headloss in the structure is not

Appendix B – SewerCAD Theory

287

significant enough to produce the expected energy loss. The modeler may accept this as a minor limitation
of the hydraulic theory, or may choose to use different structure headloss methods or values.
The reported upstream velocity and velocity head for the structure are based on the difference between the
structure's upstream EGL and HGL.

B.9.3

Design Considerations
As with any automated design, the program’s design is intended only as a preliminary step. It will select
pipe sizes, inlet lengths (StormCAD only), and pipe invert elevations based on the input provided, but no
computer program can match the skills that an experienced engineer has. The modeler should always
review any automated design, and should make any changes required to adjust, improve, and otherwise
polish the system.

B.9.4

Reporting Flow Attributes
SewerCAD has many attributes available in the FlexTables, Annotations, Color Coding, and Database/GIS
connections on different aspects of flow in a sanitary sewer system. During a Steady State analysis the
flow is broken down into categories, (I.e. wet weather, sanitary, known flow and so on). This is done so
the program can apply the correct extreme flow methods. During an Extended Period Simulation
essentially all the different flows are lumped together into a single hydrograph and the initial categories are
disregarded.
In the gravity portion of the system there are two variables that can be used in both Extended Period
Simulations and Steady State analyses. These are valuable to know if you are switching back and forth
between the two analysis modes, and would like to maintain the same reports, color coding, etc…


Total Flow - Is available for gravity pipes and gravity nodes. In gravity nodes it represents the sum of
all the flow exiting the node. In gravity pipes during a Steady State analysis it represents the sum of all
the flow entering into the pipe. In an Extended Period Simulation it represents the flow used during a
time step’s hydraulic analysis and represents a flow point on the pre-routed hydrograph.



Diverted Flow Out - Is available for gravity nodes. Represents the flow exiting the node via a
diversion.
In the pressure portion of the system, the Pressure Flow attribute for the pressure pipes shows the total
amount of flow going through the pipe for a time step, and is available for both Extended Period
Simulations and Steady State analyses.

B .10 Engineer's Reference
Coefficients


Headloss Coefficients for Manholes and Junctions

Roughness Values


Roughness Values, Manning's Equation



Roughness Values, Kutter's Equation



Roughness Values, Darcy-Weisbach (Colebrook-White) Equation



Roughness Values, Hazen-Williams Equation

288

B.10.1

Appendix B – SewerCAD Theory

Default Kinematic Viscosity
The Kinematic Viscosity is used in determining the friction coefficient in the Darcy-Weisbach Friction
Method. The default units are initially set by Haestad Methods.
To override the default value used by Haestad Methods, follow these steps:
1.

SAVE your project and Close your application.

2.

Using the Notepad Accessory in Windows, Open the HAESTAD.INI file located in the
HAESTAD directory created when you installed the product.

3.

Edit the following line in the section of the HAESTAD.INI file.

4.

DefaultKinematicViscosityInMetersSquaredPerSecond=

5.

The entry must look exactly as shown above with no spaces between attached words and the
indicated letters of each word capitalized.

6.

The value you wish to use to override the default kinematic viscosity should be inserted after the
= sign and must be in meters squared per second.

7.

Save the HAESTAD.INI file and exit Notepad.

8.

Open the program and proceed with your design.

Changing the default kinematic viscosity value in the HAESTAD.INI file will not change any
values for pipes in existing drawings. This value should only be changed before beginning new
drawings. Do not use a new value when editing an existing project created with a different
kinematic viscosity.
The program will reset the default value if this entry is left blank in the HAESTAD.INI file.

Appendix B – SewerCAD Theory

B.10.2

289

Headloss Coefficients for Junctions
These are typical headloss coefficients used in the standard method for estimating headloss through
manholes and junctions.

Typical Headloss Coefficients
Type of Manhole
Trunkline only with no bend
at the junction
Trunkline only with 45 degree
bend at junction

Trunkline only with 90 degree
bend at junction

Trunkline with one lateral

Diagram

Headloss Coefficient

0.5

0.6

0.8

Small 0.6
Large 0.7

Two roughly equivalent
entrance lines with angle < 90
degrees between lines

0.8

Two roughly equivalent
entrance lines with angle > 90
degrees between lines

0.9

Three or more entrance lines
1.0

290

B.10.3

Appendix B – SewerCAD Theory

Roughness Values - Manning's Equation
Commonly used roughness values for different materials are:
Manning’s Coefficients n for Closed Metal Conduits Flowing Partly Full
Channel Type and Description
a. Brass, smooth

Minimu
m

Normal

Maximu
m

0.009

0.010

0.013

1. Lockbar and welded

0.010

0.012

0.014

2. Riveted and spiral

0.013

0.016

0.017

1. Coated

0.010

0.013

0.014

2. Uncoated

0.011

0.014

0.016

1. Black

0.012

0.014

0.015

2. Galvanized

0.013

0.016

0.017

1. Subdrain

0.017

0.019

0.021

2. Storm drain

0.021

0.024

0.030

b. Steel

c. Cast iron

d. Wrought iron

e. Corrugated metal

B.10.4

Roughness Values - Kutter’s Equation
The roughness values for closed metal conduits flowing partly full for Kutter's Equation are the same as for
Manning's Equation.
Some commonly used roughness values for non-metal materials are:
Kutter’s Coefficients n for Closed Non-Metal Conduits Flowing Partly Full
Channel Type and Description

Minimu
m

Normal

Maximu
m

a. Lucite

0.008

0.009

0.010

b. Glass

0.009

0.010

0.013

1. Neat, surface

0.010

0.011

0.013

2. Mortar

0.011

0.013

0.015

1. Culvert, straight and free of debris

0.010

0.011

0.013

2. Culvert with bends, connections, and some
debris

0.011

0.013

0.014

c. Cement

d. Concrete

Appendix B – SewerCAD Theory

291
Minimu
m

Channel Type and Description

Maximu
m

Normal

3. Finished

0.011

0.012

0.014

4. Sewer with manholes, inlet, etc., straight

0.013

0.015

0.017

5. Unfinished, steel form

0.012

0.013

0.014

6. Unfinished, smooth wood form

0.012

0.014

0.016

7. Unfinished, rough wood form

0.015

0.017

0.020

1. Common drainage tile

0.011

0.013

0.017

2. Vitrified sewer

0.011

0.014

0.017

3. Vitrified sewer with manholes, inlet, etc.

0.013

0.015

0.017

4. Vitrified subdrain with open joint

0.014

0.016

0.018

1. Glazed

0.011

0.013

0.015

2. Lined with cement mortar

0.012

0.015

0.017

g. Sanitary sewers coated with sewage slimes,
with bends and connections

0.012

0.013

0.016

h. Paved invert, sewer, smooth bottom

0.016

0.019

0.020

i. Rubble masonry, cemented

0.018

0.025

0.030

e. Clay

f. Brickwork

B.10.5

Roughness Values - Darcy-Weisbach Equation (Colebrook-White)
Commonly used roughness values for different materials are:
Darcy-Weisbach Roughness Heights k for Closed Conduits
Pipe Material

k (mm)

k (ft)

Glass, drawn brass, copper (new)

0.0015

0.000005

Seamless commercial steel (new)

0.004

0.000013

Commercial steel (enamel coated)

0.0048

0.000016

Commercial steel (new)

0.045

0.00015

Wrought iron (new)

0.045

0.00015

Asphalted cast iron (new)

0.12

0.0004

Galvanized iron

0.15

0.0005

Cast iron (new)

0.26

0.00085

Concrete (steel forms, smooth)

0.18

0.0006

Concrete (good joints, average)

0.36

0.0012

Concrete (rough, visible, form marks)

0.60

0.002

Riveted steel (new)

0.9 ~ 9.0

0.003 - 0.03

Corrugated metal

45

0.15

292

B.10.6

Appendix B – SewerCAD Theory

Roughness Values - Hazen-Williams Formula
Commonly used roughness values for different materials are:

Hazen-Williams Roughness Coefficients C
Pipe Material

C

Asbestos Cement

140

Brass

130-140

Brick sewer

100

Cast-iron
New, unlined

130

10 yr. Old

107-113

20 yr. Old

89-100

30 yr. Old

75-90

40 yr. Old

64-83

Concrete or concrete lined
Steel forms

140

Wooden forms

120

Centrifugally spun

135

Copper

130-140

Galvanized iron

120

Glass

140

Lead

130-140

Plastic

140-150

Steel
Coal-tar enamel, lined

145-150

New unlined

140-150

Riveted

110

Tin

130

Vitrified clay (good condition)

110-140

Wood stave (average condition)

120

Appendix B – SewerCAD Theory

B.10.7

293

Typical Roughness Values for Pressure Pipes
Typical pipe roughness values are shown below. These values may vary depending on the manufacturer,
workmanship, age, and many other factors.

Comparative Pipe Roughness Values
Material

Manning’s
Coefficient

HazenWilliams

n

C

Darcy-Weisbach
Roughness Height
k (mm)

k (ft)

Asbestos Cement

0.011

140

0.0015

0.000005

Brass

0.011

135

0.0015

0.000005

Brick

0.015

100

0.6

0.002

Cast-iron, new

0.012

130

0.26

0.00085

Steel forms

0.011

140

0.18

0.006

Wooden forms

0.015

120

0.6

0.002

Centrifugally spun

0.013

135

0.36

0.0012

Copper

0.011

135

0.0015

0.000005

Corrugated metal

0.022

---

45

0.15

Galvanized iron

0.016

120

0.15

0.0005

Glass

0.011

140

0.0015

0.000005

Lead

0.011

135

0.0015

0.000005

Plastic

0.009

150

0.0015

0.000005

Coal-tar enamel

0.010

148

0.0048

0.000016

New unlined

0.011

145

0.045

0.00015

Riveted

0.019

110

0.9

0.003

Wood stave

0.012

120

0.18

0.0006

Concrete:

Steel:

Notes

Appendix C – Importing Loading Data

295

Appendix C
Importing Loading Data
C .1 Importing Loading Data Overview
SewerCAD has the capability of reading in loading data from a text file. This data includes:


Pattern data



Hydrograph data



Multiple unit sanitary loads into the same hydraulic element

• Pattern loads
The format of the file format is quite flexible, and can be easily created by copying and pasting the data
from the source application into a text editor such as Notepad.
The following help topics contain detailed information on the creation and import of the data file.

C .2 Import Loading Data Dialog
From this dialog a file is selected for import, and import parameters are specified.
To import a file:


Click on the Browse button in the File Name section to select the ASCII file to import.



Select either to Add or Replace loads.





Add Loads - If this option is toggled the imported loads will be added to the list of loads
already applied at the specified element.



Replace Loads - If this option is toggled the imported loads will overwrite any loads already
applied at the specified element.

Input data for the following options:


Flow Units - Select the units of the flow data in the import file.



Pattern Type - When importing patterns, choose whether the imported patterns are of type
Continuous or Stepwise.



Pattern Time Step - Specify the time increment of the pattern data setup in the Constant
Increment Pattern section.



Hydrograph Time Step - Specify the time increment of the hydrograph data setup in the
Constant Increment Hydrographs section.

296

Appendix C – Importing Loading Data

C .3 Loading Data Text File Format
C.3.1

ASCII Loading Data Format
SewerCAD has the ability to import various loading data from an ASCII text file. The file is divided into
sections based on the type of information being imported.
A section begins with a header, which is the name of the section typed exactly in brackets. The header is
followed by the data to be imported.
The following data sections can be imported:


[Constant Increment Patterns]



[Variable Increment Patterns]



[Sanitary Pattern Loads]



[Wet Pattern Loads]



[Constant Increment Hydrographs]



[Variable Increment Hydrographs]



[Sanitary Hydrograph Loads]



[Wet Hydrograph loads]



[Sanitary Unit Loads]

• [Options]
You do not have to enter all these sections in the import file, just the sections you are interested in
importing.
Comment lines can be placed anywhere in the file by putting a ";" at the beginning of the line.

C.3.2

Constant Increment Patterns Section
From this section of the data import file you can import pattern data directly into the Pattern Manager for
use in the model. In this section the pattern data should have a constant time increment. This time
increment is established either in the Pattern Time Step field in the Import Loading Data dialog or in the
Options section of the import file.
The format of the data is very flexible but must obey the following rules:

C.3.3



The first row of the section contains [Constant Increment Patterns] and nothing else.



The first column of each successive row of data must contain the name of the pattern for the associated
data. For example Pattern-1, Pattern 1 etc.



If the pattern name contains a space it must be surrounded by quotation marks. For example Pattern 1
should be typed as "Pattern 1."



The following columns contain the actual pattern multipliers. They can be placed in as many columns
following the pattern name as desired until you decide to go to the next row. So you could have a
single column of multipliers or a single long row of multipliers or any combination of the two.

Variable Increment Patterns Section
From this section of the data import file you can import pattern data directly into the Pattern Manager for
use in the model. In this section the pattern data can have a variable time increment.

Appendix C – Importing Loading Data

297

The format of the data is very flexible but must adhere to the following rules:

C.3.4



The first row of the section contains [Variable Increment Patterns] and nothing else.



The first column of each successive row of data must contain the name of the pattern for the associated
data. For example Pattern-1, Pattern1 etc.



If the pattern name contains a space it must be surrounded by quotation marks. For example Pattern 1
should be written as "Pattern 1"



The following columns are entered in sets of two. The first value entered is the Time from Start and
the second value is the Multiplier. These pairs can be placed in as many columns following the
pattern name until you decide to go to the next row. So you could have two columns in addition to the
pattern name for each row, or you could have a long row of time multiplier time multiplier etc… You
could also, have any combination of the two.

Sanitary Pattern Loads Section
From this section of the data import file you can import information pertaining to individual sanitary (dryweather) pattern loads and apply them to hydraulic elements.
The format of the data must adhere to the following rules:


The first row of the section contains [Sanitary Pattern Loads] and nothing else.



The first column of each successive row contains the name of the hydraulic element to import the
pattern data into. The elements must already exist in the model.
Sanitary Pattern Loads can only be imported into manholes, wet wells, and pressure junctions.

C.3.5



The second column of each successive row contains the base flow associated with the pattern load.
The unit of the flow is specified upon import in the Import Loading Data dialog.



The third column of each successive row contains the name of the pattern that is to be applied to the
pattern load. The patterns must already exist in the model or be imported in the same file as the pattern
load information.



If the names of the hydraulic elements, or the patterns contain a space then those names must be
surrounded by quotation marks. For example, Manhole 1 should be typed as "Manhole 1", and Pattern
1 should be written as "Pattern 1".

Wet Pattern Loads Section
From this section of the data import file you can import information pertaining to individual wet weather
(infiltration and inflow) pattern loads and apply them to appropriate hydraulic elements.
The format of the data must adhere to the following rules:


The first row of the section contains [Wet Pattern Loads] and nothing else.



The first column of each successive row contains the name of the hydraulic element to import the
pattern data into. The elements must already exist in the model.
Wet Pattern Loads can only be imported into manholes, pressure junctions, wet wells, and into
gravity pipes.

298

C.3.6

Appendix C – Importing Loading Data



The second column of each successive row contains the base flow associated with the pattern load.
The unit of the flow is specified upon import in the Import Loading Data dialog, or in the Options
section of the import file.



The third column of each successive row contains the name of the pattern that is to be applied to the
pattern load. The patterns must already exist in the model or be imported in the same file as the pattern
load information.



If the names of the hydraulic elements, or the patterns contain a space then those names must be
surrounded by quotation marks. For example, Manhole 1 should be typed as "Manhole 1", and Pattern
1 should be written as "Pattern 1".

Constant Increment Hydrographs Section
From this section of the data import file you can import hydrograph data into the model to be applied to a
hydraulic element. In this section the hydrograph data should have a constant time increment. This time
increment is established either in the Hydrograph Time Step field in the Import Loading Data dialog or
in the Options section of the import file.
The format of the data is very flexible but must adhere to the following rules:


The first row of the section contains [Constant Increment Hydrographs] and nothing else.



The first column of each successive row of data must contain the name of the pattern for the associated
data. For example Hydrograph-1, Hydrograph 1 etc.



If the hydrograph name contains a space it must be surrounded by quotation marks. For example,
Hydrograph 1 should be written as "Hydrograph 1."



The following columns of each successive row contain the actual flows. They can be placed in as
many columns following the hydrograph name desired until you decide to go to the next row. So you
could have a single column of flows, a single long row of flows or any combination of the two. The
unit of the flow is specified upon import in the Import Loading Data dialog, or in the Options section
of the import file.
Hydrograph information is imported through this section. You specify where the hydrographs
are applied through the Sanitary Hydrograph Loads and Wet Hydrograph Loads sections.

C.3.7

Variable Increment Hydrographs Section
From this section of the data import file you can import hydrograph data directly into the program for
distribution to various hydraulic elements.
The format of the data is very flexible but must adhere to the following rules:


The first row of the section contains [Variable Increment Hydrographs] and nothing else.



The first column of each successive row of data must contain the name of the hydrograph for the
associated data. For example Hydrograph-1, Hydrograph 1 etc.



If the hydrograph name contains a space it must be surrounded by quotation marks. For example
Hydrograph 1 should be written as "Hydrograph 1."



The following columns are entered in sets of two. The first value entered is the Time from Start and
the second value is the Flow. These pairs can be placed in as many columns following the hydrograph
name until you decide to go to the next row. So you could have two columns in addition to the
hydrograph name for each row, or you could have a long row of time flow time flow etc… You could
also, have any combination of the two. The unit of the flow is specified upon import in the Import

Appendix C – Importing Loading Data

299

Loading Data dialog, or in the Options section of the import file.
Hydrograph information is imported through this section. You specify where the hydrographs
are applied through the Sanitary Hydrograph Loads and Wet Hydrograph Loads sections.

C.3.8

Sanitary Hydrograph Loads Section
From this section of the data import file you specify to what hydraulic elements the hydrographs entered in
the Variable Increment Hydrographs and Constant Increment Hydrographs sections of the import file are
applied.
The format of the data must adhere to the following rules:


The first row of the section contains [Sanitary Hydrograph Loads] and nothing else.



The first column of each successive row contains the name of the hydraulic element to import the
pattern data into. The elements must already exist in the model.
Sanitary Hydrograph Loads can only be imported into manholes, wet wells, and pressure
junctions.

C.3.9



The second column of each successive row contains the name of the hydrograph that is to be applied to
the hydraulic element. The hydrographs referred to in this section must be imported in the same file as
the hydrograph load information.



If the names of the hydraulic elements or the hydrographs contain a space then those names must be
surrounded by quotation marks. For example, Manhole 1 should be written as "Manhole 1", and
Hydrograph 1 should be written as "Hydrograph 1".

Wet Hydrograph Loads Section
From this section of the data import file you can attribute the hydrographs entered in the Variable
Increment Hydrographs and Constant Increment Hydrographs sections of the import file to different
hydraulic elements.
The format of the data must adhere to the following rules:


The first row of the section contains [Wet Hydrograph Loads] and nothing else.



The first column of each successive row contains the name of the hydraulic element to import the
hydrograph data into. The elements must already exist in the model.
Wet Hydrograph Loads can only be imported into manholes pressure junctions, and gravity
pipes.



The second column of each successive row contains the name of the hydrograph that is to be applied to
the hydraulic element. The hydrographs referred to in this section must be imported in the same file as
the hydrograph load information.



If the names of the hydraulic elements, or the hydrograph contain a space then those names must be
surrounded by quotation marks. For example, Manhole 1 should be written as "Manhole 1", and
Hydrograph 1 should be written as "Hydrograph 1".

300

C.3.10

Appendix C – Importing Loading Data

Sanitary Unit Loads Section
From this section of the data import file you can import specific unit loads and attribute them to specified
hydraulic elements.
The format of the data must adhere to the following rules:


The first row of the section contains [Sanitary Unit Loads] and nothing else.



The first column of each successive row contains the name of the hydraulic element to import the
sanitary unit load into.
Sanitary Unit Loads can only be imported into manholes, wet wells, and pressure junctions.

C.3.11



The second row of each successive column contains the name of the Unit Sanitary (Dry Weather)
Load. For example, Airport, Home (Residential), etc… The Unit Sanitary Load must already be
specified in the Engineering Libraries for it to be correctly applied.



The third row of each successive column contains a number, the Unit Load count.



If the names of the hydraulic elements, or the Unit Sanitary Load contain a space then the name must
be surrounded by quotation marks. For example, Manhole 1 should be written as "Manhole 1", and
Bar per Customer should be written as "Bar per Customer".

Options Section
From this section you can initialize the option parameters on the Import Loading Data dialog. This
initialization occurs upon selection of the import file in the dialog.
You can read in data for the following parameters:


Pattern Time Step - set to a positive numerical value.



Hydrograph Time Step - set to a positive numerical value.



Flow Units - set to one of the units selectable from the Flow Units field in the Import Loading Data
dialog.
If the flow unit contains a superscript such as m3/s, you can add the superscript by using
Character Map, which is a standard Windows application, which can be opened through the
Accessories directory in the Start menu. Otherwise simply select the unit in the Flow Units field
on the Import Loading Data dialog.

• Pattern Type - set to either Continuous or Stepwise.
The format of the data must adhere to the following rules:


The first row of the section contains [Options] and nothing else.



Each successive row of the section (up to four) contains the name of the parameter typed exactly as
presented above; followed by a space; followed by an equal sign; followed by a space, and then the
value of the parameter.
The Options section is not required for the data import to run successfully, and beyond that you
only have of specify parameters for the options that you require.
The Options section only initializes the values on the Import Loading Data dialog. If you change
the values in the dialog after specifying the import file, the values in the dialog will be used.

Appendix C – Importing Loading Data

C.3.12

ASCII Loading Data Example
This help topic contains a sample ASCII Loading File, and contains sample data for all the different
sections that are capable of import. Note the variability in the way columns and rows can be setup, and
how items can be named.
[Constant Increment Patterns]
Pattern-1 1.0 2.0 3.0
Pattern-1 3.0 2.0 1.0
[Variable Increment Patterns]
; This is information about
; this pattern set on two comment lines.
"Pattern 2" 1.5 1.0 2.5 2.0 3.0 3.0
"Pattern 2" 4.0 2.0 5.5 1.0
[Sanitary Pattern Loads]
MH-1 100.0 "Pattern-1"
MH-1 200.0 "Pattern 2"
[Wet Pattern Loads]
"MH-1" 100.0
Pattern-1
"MH-1" 200.0
"Pattern 2"
[Constant Increment Hydrographs]
"Hydrograph 1" 1.0
2.0
3.0
"Hydrograph 1" 3.0
2.0
1.0
[Variable Increment Hydrographs]
Hydrograph-2 0.25 0.501302
Hydrograph-2 0.50 1.002604
Hydrograph-2 1.00 2.005208
Hydrograph-2 1.50 3.007813
Hydrograph-2 2.00 3.007813
Hydrograph-2 2.50 2.005208
Hydrograph-2 3.00 1.002604
[Sanitary Hydrograph Loads]
MH-1 "Hydrograph 1"
MH-1
Hydrograph-2
J-1
"Hydrograph 1"
[Wet Hydrograph Loads]
"MH-1" "Hydrograph 1"
"MH-1" Hydrograph-2
"P-1"
“Hydrograph 1”
[Sanitary Unit Loads]
"MH-1" "Airport"
"MH-1" "Apartment"
"J-1"
"Airport"
[Options]
Pattern Time Step = 0.25
Hydrograph Time Step = 0.5
Flow Units = cfs
Pattern Type = Continuous

53.0
500.0
53.0

301

Notes

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303

Appendix D
Scenario Management
Reference Guide
D .1 Overview
Haestad Methods’ scenario management feature can dramatically increase your productivity in the "What
If?" areas of modeling, including calibration, operations analysis, and planning.
By investing a little time now to understand scenario management, you can avoid unnecessary editing and
data duplication. Take advantage of scenario management to get a lot more out of your model, with much
less work and expense.
In contrast to the old methods of scenario management (editing or copying data), automated scenario
management using inheritance gives you significant advantages:


A single project file makes it possible to generate an unlimited number of "What If?" conditions
without becoming overwhelmed with numerous modeling files and separate results.



Because the software maintains the data for all the scenarios in a single project, it can provide you with
powerful automated tools for directly comparing scenario results. Any set of results is immediately
available at any time.



The Scenario / Alternative relationship empowers you to mix and match groups of data from existing
scenarios without having to re-declare any data.



With inheritance, you do not have to re-enter data if it remains unchanged in a new alternative or
scenario, avoiding redundant copies of the same data. Inheritance also enables you to correct a data
input error in a parent scenario and automatically update the corrected attribute in all child scenarios.
These advantages, while obvious, may not seem compelling for small projects. It is as projects grow to
hundreds or thousands of network elements that the advantages of true scenario inheritance become clear.
On a large project, being able to maintain a collection of base and modified alternatives accurately and
efficiently can be the difference between evaluating optional improvements and being forced to ignore
them.

D .2 About this Guide
The depth of scenario management as implemented by Haestad Methods is probably far beyond what you
have ever seen before. With that in mind, this guide is intended as an introduction to the philosophy and
terminology upon which scenario management is based.
This is not intended as a step-by-step guide to using the software. If you are a moderately experienced
Windows software user, you should have no difficulty learning and exploring the scenario management
interface.

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Excellent tutorials and context-sensitive on-line help are also available within the software itself. These
learning tools will prove to be of tremendous assistance to you for all aspects of the software, and should
certainly not be ignored if you are having difficulty. For more information, just click the Help button,
which is available from anywhere within the program. In addition, contact Haestad Methods for the
schedule of the workshops that are held around the country.

D .3 Before Haestad Methods: Distributed Scenarios
Let us begin by understanding the approaches that have historically been used to attempt "What If?"
analyses. Traditionally, there have only been two possible ways of analyzing the effects of change on a
software model:


Change the model, recalculate, and review the results

• Create a copy of the model, edit that copy, calculate, and review the results
Although either of these methods may be adequate for a relatively small system, the data duplication,
editing, and re-editing becomes very time-consuming and error-prone as the size of the system - and the
number of possible conditions - increase. Additionally, comparing conditions requires manual data
manipulation, because all output must be stored in physically separate data files.

Before Haestad Methods: Distributed Scenarios

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305

D .4 With Haestad Methods: Self-Contained Scenarios
Effective scenario management tools need to meet these objectives:


Minimize the number of project files the modeler needs to maintain (one, ideally).



Maximize the usefulness of scenarios through easy access to things such as input and output data, and
direct comparisons.



Maximize the number of scenarios you can simulate by mixing and matching data from existing
scenarios (data reuse)



Minimize the amount of data that needs to be duplicated to consider conditions that have a lot in
common
The scenario management feature developed by Haestad Methods successfully meets all of these
objectives. A single project file enables you to generate an unlimited number of "What If?" conditions, edit
only the data that needs to be changed, and quickly generate direct comparisons of input and results for
desired scenarios.

D .5 The Scenario Cycle
The process of working with scenarios is similar to the process of manually copying and editing data, but
without the disadvantages of data duplication and troublesome file management. This process allows you
to cycle through any number of changes to the model, without fear of overwriting critical data or
duplicating important information. Of course, it is possible to directly change data for any scenario, but an
"audit trail" of scenarios can be useful for retracing the steps of a calibration series or for understanding a
group of master plan updates.

With Haestad Methods: Self-contained Scenarios

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D .6 Scenario Anatomy: Attributes and Alternatives
Before we explore scenario management further, a few key terms should be defined:
Attribute - An attribute is a fundamental property of an object, and is often a single numeric quantity. For
example, the attributes of a pipe include diameter, length, and roughness.
Alternative - An alternative holds a family of related attributes so pieces of data that you are most likely to
change together are grouped for easy referencing and editing. For example, a physical properties
alternative groups physical data for the network’s elements, such as elevations, sizes, and roughness
coefficients.
Scenario - A scenario has a list of referenced alternatives (which hold the attributes), and combines these
alternatives to form an overall set of system conditions that can be analyzed. This referencing of
alternatives enables you to easily generate system conditions that mix and match groups of data that have
been previously created. Note that scenarios do not actually hold any attribute data - the referenced
alternatives do.

D .7 A Familiar Parallel
Although the structure of scenarios may seem a bit difficult at first, anyone who has eaten at a restaurant
should be able to relate fairly easily. A meal (scenario) is comprised of several courses (alternatives),
which might include a salad, an entrée, and a dessert. Each course has its own attributes. For example, the
entrée may have a meat, a vegetable, and a starch. Examining the choices, we could present a menu as in
the following figure:

A Restaurant Meal "Scenario"

The restaurant does not have to create a new recipe for every possible meal (combination of courses) that
could be ordered. They can just assemble any meal based on what the customer orders for each alternative
course. Salad 1, Entrée 1, and Dessert 2 might then be combined to define a complete meal.
Generalizing this concept, we see that any scenario simply references one alternative from each category to
create a "big picture" that can be analyzed. Note that different types of alternatives may have different
numbers and types of attributes, and any category can have an unlimited number of alternatives to choose
from.

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307

Generic Scenario Anatomy

D .8 Scenario Behavior: Inheritance
The separation of scenarios into distinct alternatives (groups of data) meets one of the basic goals of
scenario management: maximizing the number of scenarios you can develop by mixing and matching
existing alternatives. Two other primary goals have also been addressed: a single project file is used, and
easy access to input data and calculated results is provided in numerous formats through the intuitive
graphical interface.
But what about the other objective: minimizing the amount of data that needs to be duplicated to consider
conditions that have a lot of common input? Surely an entire set of pipe diameters should not be respecified if only one or two change?
The solution is a familiar concept to most people: inheritance.
In the natural world, a child inherits characteristics from a parent. This may include such traits as eyecolor, hair color, and bone structure. There are two significant differences between the genetic inheritance
that most of us know and the way inheritance is implemented in software:


Overriding inheritance



Dynamic inheritance

D .9 Overriding Inheritance
Overriding inheritance is the software equivalent of cosmetics. A child can override inherited
characteristics at any time by specifying a new value for that characteristic. These overriding values do not
affect the parent, and are therefore considered "local" to the child. Local values can also be removed at any
time, reverting the characteristic to its inherited state. The child has no choice in the value of his inherited
attributes, only in local attributes.
For example, suppose a child has inherited the attribute of blue eyes from his parent. Now the child puts on
a pair of green- tinted contact lenses to hide his natural eye color. When the contact lenses are on, we say
his natural eye color is "overridden" locally, and his eye color is green. When the child removes the tinted
lenses, his eye color instantly reverts to blue, as inherited from his parent.

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D .10 Dynamic Inheritance
Dynamic inheritance does not have a parallel in the genetic world. When a parent’s characteristic is
changed, existing children also reflect the change. Using the eye-color example, this would be the
equivalent of the parent changing eye color from blue to brown, and the children’s eyes instantly inheriting
the brown color also. Of course, if the child has already overridden a characteristic locally, as with the
green lenses, his eyes will remain green until the lenses are removed. At this point, his eye color will revert
to the inherited color, now brown.
This dynamic inheritance has remarkable benefits for applying wide-scale changes to a model, fixing an
error, and so on. If rippling changes are not desired, the child can override all of the parent’s values, or a
copy of the parent can be made instead of a child.

D .11 When are Values Local, and When are They Inherited?
Any changes that are made to the model belong to the currently active scenario and the alternatives that it
references. If the alternatives happen to have children, those children will also inherit the changes unless
they have specifically overridden that attribute. The following figure demonstrates the effects of a change
to a mid-level alternative. Inherited values are shown as gray text, local values are shown as black text.

A Mid-level Hierarchy Alternative Change

D .12 Minimizing Effort through Attribute Inheritance
Inheritance has an application every time you hear the phrase "just like x except for y". Rather than
specifying all of the data from x again to form this new condition, we can simply create a child from x and
change y appropriately. Now we have both conditions, with no duplicated effort.
We can even apply this inheritance to our restaurant analogy as follows. Inherited values are shown as gray
text, local values are shown as black text.



"Salad 2 is just like Salad 1, except for the dressing."



"Salad 3 is just like Salad 1, except for the dressing."
Salad 3 could inherit from Salad 2, if we prefer: "Salad 3 is just like Salad 2, except for the
dressing."

Appendix D – Scenario Management Reference Guide



"Entrée 2 is just like Entrée 1, except for the meat and the starch."



"Entrée 3 is just like Entrée 2, except for the meat."

309

If the vegetable of the day changes (say from green beans to peas), only Entrée 1 needs to be
updated, and the other entrées will automatically inherit the vegetable attribute of "Peas"
instead of "Green Beans".



"Dessert 2 is just like Dessert 1, except for the topping."
Dessert 3 has nothing in common with the other desserts, so it can be created as a "root" or
"base" alternative. It does not inherit its attribute data from any other alternative.

D .13 Minimizing Effort through Scenario Inheritance
Just as a child alternative can inherit attributes from its parent, a child scenario can inherit which
alternatives it references from its parent. This is essentially still the phrase "just like x except for y", but on
a larger scale.
Carrying through on our meal example, consider a situation where you go out to dinner with three friends.
The first friend places his order, and the second friend orders the same thing except for the dessert. The
third friend orders something totally different, and you order the same meal as hers except for the salad.
The four meal "scenarios" could then be presented as follows (inherited values are shown as gray text, local
values are shown as black text):



"Meal 2 is just like Meal 1, except for the dessert." The salad and entrée alternatives are inherited from
Meal 1.



"Meal 3 is nothing like Meal 1 or Meal 2." A totally new "base" or "root" is created.

310


Appendix D – Scenario Management Reference Guide
"Meal 4 is just like Meal 3, except for the salad." The entrée and dessert alternatives are inherited from
Meal 3.

D .14 A Water Distribution Example
Let us consider a fairly simple water distribution system: a single reservoir supplies water by gravity to
three junction nodes.

Example Water Distribution System

Although true water distribution scenarios include such alternative categories as initial settings, operational
controls, water quality, and fire flow, we are going to focus on the two most commonly changed sets of
alternatives: demands and physical properties. Within these alternatives, we are going to concentrate on
junction baseline demands and pipe diameters.

D .15 Building the Model (Average Day Conditions)
During model construction, probably only one alternative from each category is going to be considered.
This model is built with average demand calculations and preliminary pipe diameter estimates. At this
point we can name our scenario and alternatives, and the hierarchies look like the following (showing only
the items of interest):

Appendix D – Scenario Management Reference Guide

311

D .16 Analyzing Different Demands (Maximum Day Conditions)
In our example, the local planning board also requires analysis of maximum day demands, so a new
demand alternative is required. No variation in demand is expected at J-2, which is an industrial site. As a
result, the new demand alternative can inherit J-2’s demand from "Average Day" while the other two
demands are overridden.

Now we can create a child scenario from "Average Day" that inherits the physical alternative, but overrides
the selected demand alternative. As a result, we get the following scenario hierarchy:

Since no physical data (pipe diameters) have been changed, the physical alternative hierarchy remains the
same as before.

D .17 Another Set of Demands (Peak Hour Conditions)
Based on pressure requirements, the system is adequate to supply maximum day demands. Another local
regulation requires analysis of peak hour demands, with slightly lower allowable pressures. Since the peak
hour demands also share the industrial load from the "Average Day" condition, "Peak Hour" can be
inherited from "Average Day". In this instance, "Peak Hour" could inherit just as easily from "Maximum
Day".

Another scenario is also created to reference these new demands, as shown below:

Note again that we did not change any physical data, so the physical alternatives remain the same.

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D .18 Correcting an Error
This analysis results in acceptable pressures, until it is discovered that the industrial demand is not actually
500 gpm - it is 1,500 gpm! Because of the inheritance within the demand alternatives, however, only the
"Average Day" demand for J-2 needs to be updated. The changes will ripple through to the children. After
the single change is made, the demand hierarchy is as follows:

Notice that no changes need to be made to the scenarios to reflect these corrections. The three scenarios
can now be calculated as a batch to update the results.
When these results are reviewed, it is determined that the system does not have the ability to adequately
supply the system as it was originally thought. The pressure at J-2 is too low under peak hour demand
conditions.

D .19 Analyzing Improvement Suggestions
To counter the headloss from the increased demand load, two possible improvements are suggested:


A much larger diameter is proposed for P-1 (the pipe from the reservoir). This physical alternative is
created as a child of the "Preliminary Pipes" alternative, inheriting all the diameters except P-1’s,
which is overridden.



Slightly larger diameters are proposed for all pipes. Since there are no commonalities between this
recommendation and either of the other physical alternatives, this can be created as a base (root)
alternative.
These changes are then incorporated to arrive at the following hierarchies:

This time, the demand alternative hierarchy remains the same since no demands were changed. The two
new scenarios ("Peak, Big P-1", "Peak, All Big Pipes") can be batch run to provide results for these
proposed improvements.
Next, features like Scenario Comparison Annotation (from the Scenario Manager) and comparison Graphs
(for extended period simulations, from the element editor dialogs) can be used to directly determine which
proposal results in the most improved pressures.

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313

D .20 Finalizing the Project
It is decided that enlarging P-1 is the optimum solution, so new scenarios are created to check the results
for average day and maximum day demands. Notice that this step does not require handling any new data.
All of the information we want to model is present in the alternatives we already have!

Also note that it would be equally effective in this case to inherit the "Avg. Day, Big P-1" scenario from
"Avg. Day" (changing the physical alternative) or to inherit from "Peak, Big P-1" (changing the demand
alternative). Likewise, "Max. Day, Big P-1" could inherit from either "Max. Day" or "Peak, Big P-1".
Neither the demand nor physical alternative hierarchies were changed in order to run the last set of
scenarios, so they remain as they were.

D .21 Summary
In contrast to the old methods of scenario management (editing or copying data), automated scenario
management using inheritance gives you significant advantages:


A single project file makes it possible to generate an unlimited number of "What If?" conditions
without becoming overwhelmed with numerous modeling files and separate results.



Because the software maintains the data for all the scenarios in a single project, it can provide you with
powerful automated tools for directly comparing scenario results. Any set of results is immediately
available at any time.



The Scenario / Alternative relationship empowers you to mix and match groups of data from existing
scenarios without having to re-declare any data.



With inheritance, you do not have to re-enter data if it remains unchanged in a new alternative or
scenario, avoiding redundant copies of the same data. Inheritance also enables you to correct a data
input error in a parent scenario and automatically update the corrected attribute in all child scenarios.

314

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These advantages, while obvious, may not seem compelling for small projects. It is as projects grow to
hundreds or thousands of network elements that the advantages of true scenario inheritance become clear.
On a large project, being able to maintain a collection of base and modified alternatives accurately and
efficiently can be the difference between evaluating optional improvements and being forced to ignore
them.

D .22 Conclusion
These are the fundamental concepts behind the architecture of Haestad Methods’ scenario management. To
learn more about actually using scenario management in Haestad Methods software, start by running the
scenario management tutorial from the Help menu or from within the scenario manager itself. Then load
one of the SAMPLE projects and explore the scenarios defined there. For context-sensitive help, press F1
or the Help button any time there is a screen or field that puzzles you.
Haestad Methods’ scenario management feature gives you a powerful tool for modeling real-world
engineering scenarios when analyzing system response to different demands, reviewing the impacts of
future growth, and iterating to find the least expensive design. That means you will be able to finish your
projects faster, spend less money, and improve your bottom line.

Appendix E – Haestad Methods Software

315

Appendix E
Haestad Methods Software
E .1 Overview
Haestad Methods offers software solutions to civil engineers throughout the world for analyzing, modeling,
and designing all sorts of hydrologic and hydraulic systems, from municipal water and sewer systems to
stormwater ponds, open channels, and more. With point-and-click data entry, flexible units, and reportquality output, Haestad Methods is the ultimate source for your modeling needs.
In addition to the ability to run in Stand-Alone mode with a CAD-like interface, three of our products WaterCAD, StormCAD and SewerCAD - can be totally integrated within AutoCAD. These three
programs also share numerous powerful features, such as scenario management, unlimited undo/redo,
customizable tables for editing and reporting, customizable GIS, database and spreadsheet connection, and
annotation.
Be sure to contact us or visit our web site at www.haestad.com to find out about our latest software, books,
training, and open houses.

E .2 WaterCAD
WaterCAD is the definitive model for complex pressurized pipe networks, such as municipal water
distribution systems. You can use WaterCAD to perform a variety of functions, including steady-state and
extended-period simulations of pressure networks with pumps, tanks, control valves, and more.
WaterCAD’s abilities also extend into public safety and long-term planning issues, with extensive water
quality features, automated fire protection analyses, comprehensive scenario management, and enterprisewide data sharing faculties.
WaterCAD is available with your choice of a Stand-Alone graphical user interface, an AutoCAD integrated
interface, or an ArcView or ArcInfo integrated interface.

E .3 SewerCAD
SewerCAD is a powerful design and analysis tool for modeling sanitary sewage collection and pumping
systems. With SewerCAD, you can develop and compute sanitary loads, tracking and combining loads
from dry-weather and wet-weather sources. You can also simulate the hydraulic response of the entire
system (gravity collection and pressure force mains), observe the effects of overflows and diversions, and
even automatically design selected portions of the system. Output covers everything from customizable
tables and detailed reports to plan and profile sheets.
SewerCAD can be run in a Stand-Alone graphical user interface, an AutoCAD integrated interface, or an
ArcView or ArcInfo integrated interface.

316

Appendix E – Haestad Methods Software

E .4 StormCAD
StormCAD is a highly-efficient model for the design and analysis of storm sewer collection systems.
From graphical layout and intelligent network connectivity to flexible reports and profiles, StormCAD
covers all aspects of storm sewer modeling.
Surface inlet networks are independent of pipe connectivity, and inlet hydraulics conform to FHWA HEC22 methodologies. Gradually varied flow algorithms and a variety of popular junction loss methods are the
foundation of StormCAD’s robust gravity piping computations, which handle everything from surcharged
pipes and diversions to hydraulic jumps.
StormCAD is available with your choice of a Stand-Alone graphical user interface, an AutoCAD integrated
interface, or an ArcView or ArcInfo integrated interface.

E .5 PondPack
PondPack is a comprehensive, Windows-based hydrologic modeling program that analyzes a tremendous
range of situations, from simple sites to complex networked watersheds. The program analyzes pre- and
post-developed watershed conditions, and estimates required storage ponds. PondPack performs
interconnected pond routing, and also computes outlet rating curves with tailwater effects, multiple outfalls,
pond infiltration, and pond detention times.
PondPack builds customized reports organized by categories, and automatically creates section and page
numbers, tables of contents, and indexes. You can quickly create an executive summary for an entire
watershed, or build an elaborate drainage report showing any or all report items. Graphical displays, such
as watershed diagrams, rainfall curves, and hydrographs are fully compatible with other Windows’s
software, such as AutoCAD.

E .6 CulvertMaster
CulvertMaster helps engineers design new culverts and analyze existing culvert hydraulics, from single
barrel crossings to complex multi-barrel culverts with roadway overtopping. CulvertMaster computations
use FHWA HDS-5 methodologies, and allow you to solve for whatever hydraulic variables you don’t
know, such as culvert size, peak discharge, and headwater elevation. Output capabilities include
comprehensive detailed reports, rating tables, and performance curves.

E .7 FlowMaster
FlowMaster is an efficient program for the design and analysis of a wide variety of hydraulic elements,
such as pressure pipes, open channels, weirs, orifices, and inlets. FlowMaster's "Hydraulics Toolbox" can
create rating tables and performance curves for any variables, using popular friction methods. Inlet
calculations follow the latest FHWA guidelines, and irregular section roughness can be weighted based on
any popular techniques.

Glossary

317

Glossary
AASHTO Headloss Method - Automatic Computation of the junction loss based on the geometry of the
junction, which accounts for bend loss, based on the upstream pipes angle, as defined in the AASHTO
Model Drainage Manual (1991).
AASHTO Shaping Method - Specifies whether the junction bottom is designed with a partial diameter
shaping or not. See Headloss - AASHTO Method.
Absolute Headloss - A user specified headloss - See Absolute Headloss Method.
Absolute Roughness - Average height of roughness particles in the channel.
Additional Infiltration - Lumped infiltration amount.
Average Velocity - Average water velocity in the pipe. The following methods are available for
calculating the average velocity: Uniform Flow, Full Flow, Simple Average and Weighted Average.
Refer to the theory chapter for explanations.
Base Load - Average local sanitary load calculated by multiplying the Unit Base Load by the Loading
Unit Count for every Unit Sanitary Load category (for instance Apartment or Airport) at a loading point.
Bend Loss Coefficient - Bend Loss Coefficient K used in AASHTO equation for structure headloss
calculations.
Bend Angle -Angle between the pipe and the downstream pipe, measured as a deflection angle. Note that
this angle is used in the HEC22 and AASHTO junction loss methods.
Bolted Cover - Indicates whether a manhole is bolted. If the manhole is bolted, then the hydraulic grade
line is not reset to the rim elevation at the downstream end of the upstream pipe(s) in the case of a
flooding situation (the calculated HGL being higher than the rim elevation).
Calculated Hydraulic Grade - Hydraulic Grade in the wet well calculated as explained in the Hydraulic
Transition from Gravity to Pressure Network section in the Theory chapter.
Cancel Button - When you click on this button, it cancels the command you chose and closes the dialog.
Capacity - The effective carrying ability of a drainage structure. The discharge of the pipe or closed
channel under the filled condition computed with the friction slope equal to the constructed slope. For
discharges greater than the capacity, the friction slope exceeds the constructed slope.
C Coefficient - Roughness coefficient used in the Hazen-Williams Equation.
Channel Invert - Lowest point on the surface of a channel cross section.

318

Glossary

Channel Slope - Longitudinal slope in the channel. Also the vertical drop divided by the channel length.
In irregular channels, the vertical drop is measured from low point to low point.
Check Valve - When this check box is toggled, flow can only travel from the From Node to the To Node
in a pressure pipe.
Click - To quickly press and release one of the mouse buttons.
Closed Channel - A channel with a perimeter that forms a continuous closed boundary.
Constructed Slope - The average slope of the pipe inverts. The difference in the invert elevations
between the upstream end and downstream end of the pipe divided by its length.
Context Menu - A pop-up menu opened by a right mouse click on a project element or data entry field.
Commands on the context menu are specific to the current context state of the selected item.
Contraction - Adjustment coefficient used in the AASHTO equation to account for contraction of the
flow at the entrance in the outlet pipe.
Control Status - A pressure pipe can be either Open or Closed. Open means that flow occurs in the pipe
and Closed means that no flow occurs in the pipe.
Conveyance Element - A pipe or channel used to transport water.
Cover - Distance between the crown (soffit) of the pipe and the ground surface elevation.
Critical Depth - Depth of water in the channel for which the specific energy is at its minimum.
Rectangular:

 Q2
Yc =  2
 gT






1

3

Non-rectangular (implicit solution, solving for Yc):

Yc = gA 3 − Q 2 T
Where:

A =

Flow Area (m², ft²)

g =

gravitational acceleration (m/s², ft/s²)

Q =

discharge (m³/s, cfs)

T =

Top Width (m, ft)

Yc =

Critical Depth (m, ft)

Critical Flow - Flow through a channel for which the specific energy is at its minimum.

Glossary

319

Critical Slope - Channel or pipe slope for which the uniform flow is critical.
Crosshair - Shape of the cursor that looks like a plus sign ( + ).
Crown (or Soffit) - Top edge or the highest point of the pipe opening.
Cutoff Value - The cutoff value defines the maximum possible extreme flow factor for peaking methods
or the minimum possible extreme flow factor for daily minimum methods. The generic equation used to
calculate the extreme flow factor converges towards infinity as the population approaches 0. The cutoff
value prevents unreasonably large extreme flow factors. The figure shows a cutoff value of 2.

For minimum daily flows, extreme flow factor methods cutoff value limits how small an extreme
flow factor can be.
Database Connections - A connection represents a group of database links. There may be just a single
linked external file within a connection, or there may be hundreds of external file links within a single
connection.
DBMS - An acronym which stands for Database Management System. These systems can be relational
(RDBMS) or non-relational.
Depth - See flow depth.
Design Point - The design point of a pump is the point at which the pump was originally intended to
operate, and is typically the best efficiency point (BEP) of the pump. At discharges above or below this

320

Glossary

point, the pump is not operating under optimum conditions.
Design Sump Depth - A positive value will design a gravity structure with a sump elevation the Design
Sump Depth below the downstream pipe invert elevation. In other words, the design sump depth is the
distance below the lowest pipe invert that you wish to set the sump.
Diameter - Inside diameter of a circular channel, unless stated otherwise.
Discharge - Volumetric rate of flow given in units of length³/Time.
Display Precision - In worksheets, rating tables, curves, and cross sections, the rounding of numbers and
the number of digits displayed after the decimal point.
Diversion - A gravity node that diverts a portion of the flow out. A diversion element has two outlets
while standard gravity elements have only one downstream pipe.
Diversion Rating Curve Table - A table that defines diverted flows as a function of total upstream flow.
Diversion Target - Destination for flows diverted out of a diversion element.
Double-Click - To click one of the mouse buttons (usually the left button) twice in rapid succession.
Drag - To hold down one of the mouse buttons (usually the left button) while you move the mouse.
Duration - The amount of time modeled during an Extended Period Simulation.
Element - An object, such as a manhole, outlet, or gravity pipe in a drawing.
Elevation - The elevation of an element is the distance from the datum plane to the center of the element.
Elevations are often referenced with mean sea level as the datum elevation.
Elevations Considered Equal Within - The correction factor for relative flow (CQ) is applied only to
situations where there are two or more pipes entering the structure at approximately the same elevation.
Elevations Considered Equal Within is used to determine the maximum differences in pipe elevation for
which the pipes are still considered approximately the same elevation.
Energy - Total energy of flow with reference to a datum. Computed for closed channels as the sum of
channel centerline height above datum, piezometric height, and the velocity head. Computed for open
channels as the sum of channel invert height above datum, the flow depth, and velocity head.

Glossary

321

Energy Equation - The energy relationship between the downstream and upstream end of a pipe is:

V12 P1
V2 P
+ + z1 + h G = 2 + 2 + z 2 + h L
2g
?
2g
?
Where:

V =

fluid velocity (m²/s, ft²/s)

g =

gravitational acceleration (m/s², ft/s²)

P =

pressure (N/m², lb/ft²)

γ =

specific weight of the fluid (N/m³,lb/ft³)

z =

elevation at the centroid (m, ft)

hG =

head gain, such as from a pump (m, ft)

hL =

combined headloss (m, ft)

Energy Grade Line - Sum of datum (base elevation), velocity head, and pressure head at a section.
Energy Slope - The energy grade at each end of the pipe is computed by adding the velocity head
component to the hydraulic grade. The energy slope is calculated by dividing the change in energy grade
by the length of pipe.
Exit Discharge - Discharge in the pipe downstream of the structure.
Exit Velocity - Velocity at the upstream end of the pipe downstream of the structure.
Exit Velocity Head - Velocity head at the upstream end of the pipe downstream of the structure.
Expansion - Adjustment coefficient used in AASHTO equation to account for expansion of the flow on
the exit from an incoming pipe.
Extended Period Simulation (EPS) - A calculation type where the model is analyzed over a specified
duration of time. See also Steady-State Analysis.
Extension - The period and up to three characters at the end of a filename. An extension usually
identifies the kind of information the file contains. For example, files you create in AutoCAD have the
extension *.DWG.
External Files - Any file outside of the program that can be linked to. These include database files (such
as FoxPro, Dbase, or Paradox), spreadsheets (such as Excel or Lotus), and ODBC connect strings.
Throughout the documentation, all of these file types will be referred to as "databases" or "external files"
interchangeably.

322

Glossary

Extrapolate - Infer a value based on other values in an interval as in interpolation, with the value lying
outside the known range of values.

Yu − Y1 X K − X 1
=
Y2 − Y1 X 2 − X 1
Where:

YU = unknown value in Y
XK =

known value in X

X1, X2, Y1, Y2= known table values
Field Links - Within each database table, the field links define the actual mapping between model
element attributes and columns in the database.
Flow - Volumetric rate of flow given in units of length³ / time in the pipe or channel. Common units of
flow are cfs, gpm, liters/sec, and cms.
Flow Area - Cross sectional area of flow.
Flow Depth - Distance from water level to low point of channel bottom.
Flow Type - The flow is defined as:


Supercritical if F > 1



Subcritical if F < 1

• Critical if F =1
Where: F = Froude number.
Friction Factor - Friction Coefficient used in the Darcy-Weisbach Formula.
Friction Slope - Given a depth, roughness, section shape, friction method, and discharge, the friction
slope is the computed slope that would be required to convey the specified discharge under uniform flow
conditions. Under uniform flow conditions, depth and flow area are constant and the friction slope, the
actual or constructed slope, and the energy slope are all equal.
Under gradually varied flow conditions, the depth of flow is changing along the channel and the friction
slope is also varying. In the model’s gradually varied flow solution, the friction slope between an upstream
and downstream location along a prismatic channel is computed by taking the average of the uniform flow
based friction slopes calculated at the beginning and ending stations of the sub-reach.

Glossary

323

Froude Number - The Froude number is a unitless value representing the ratio of actual fluid velocity to
wave celerity. It is computed as:

F=

V
g⋅D

F = Froude number (unitless)
V = Velocity (m/s, ft/s)
D = Hydraulic depth (m, ft)
g
= Gravitational acceleration (m/s², ft/s²)
At critical depth, the Froude number is equal to 1.0.
Where:

Full Flow - Closed channel is flowing full, or entire channel perimeter is touched by flowing water
(wetted).
Full Flow Capacity - The computed discharge when a closed channel is flowing full.
Full Flow Slope - The computed channel slope that would produce full flow.
Global Diverted Flow - The diverted flow entering a gravity node from one or more nodes located in
other networks.
Gravity - Our products use these constants for all equations with g, gravity.
US:

32.174 ft/s²

Metric: 9.81

m/s²

Ground Elevation - The elevation of the ground surface at a node.
Headloss - Loss of energy due to friction and minor losses.
Headloss Coefficient - See Headloss Coefficient - Standard Method.
Headloss Gradient - Headloss in a pipe or channel represented as a slope, or gradient. This allows you
to more accurately compare headlosses for pipes of different lengths.
Headloss Method - This program use one of the following methods to calculated headloss across a
structure: Standard Headloss Method, Absolute Headloss Method, HEC-22 Energy Headloss Method or
AASHTO Headloss Method.
HEC-22 Benching Method - Specifies which correction factor for benching is to be used, as specified in
table 7-6 p. 7-19 of the FHWA HEC-22 manual used in the HEC-22 Energy Method.
HEC-22 Energy Loss Method - See Headloss HEC-22 Energy Method.
HGL - See hydraulic grade line.

324

Glossary

HGL In/Out
− HGL In: The hydraulic grade at the downstream end of the incoming pipe section.
− HGL Out: The hydraulic grade at the upstream end of the outgoing pipe section.
Hydraulic Grade - See hydraulic grade line.
Hydraulic Grade Line - Hydraulic grade is computed using Gradually varied flow analysis in free
surface conditions or by computing a pressure backwater starting from the submerged hydraulic grade at
the downstream end of the pipe to the upstream end of the pipe, or a combination of free-surface and
pressure. In open channels the hydraulic grade is equal to the water surface elevation.
Hydraulic Radius - Flow area divided by wetted perimeter.
Hydraulic Time Step - The time increment between hydraulic backwater analyses in the gravity portions
of the system during an Extended Period Simulation.
Hydrograph - A graph of discharge vs. time.
Hydrologic Time Step - The time increment used when routing hydrographs in the gravity portion of the
network, as well as the time increment used when running the pressure calculations.
Inflow - The Inflow is specified at a manhole or wet well as the total amount of wet weather inflow.
Together with the infiltration along the pipes, the inflow forms the wet weather part of the sewer load.
Interpolate - A way of estimating a value between two known values assuming a linear relation.

Yu − Y1 X K − X 1
=
Y2 − Y1 X 2 − X 1
Where:

YU =

unknown value in Y

XK =

known value in X

X1, X2, Y1, and Y2 = known table values
Invert - Bottom edge (lowest point) of the pipe opening. Sometimes referred to as the flow line.
Invert Elevation - The elevation at the bottom of the pipe. The invert elevation is the lowest point of the
pipe opening.
Junction - Two or more pipes coming together.
Kinematic Viscosity - Viscosity divided by the mass density given in units of length3/time, thus the term,
kinematic.
Known Flow - Use the Known Flow field to model discharges at locations in the network where you
have computed the hydrology using an external method (e.g. TR-55 tabular method).

Glossary

325

During a Steady State analysis known flows are not additive except at network junctions. The Known
Flow component will remain constant until it encounters a downstream Known Flow of a different value.
During an Extended Period Simulation known flows are treated as a constant inflow hydrograph and
lumped in with other hydrographs entering at the same point. Known Flows are additive during Extended
Period Simulations.
Kutter's n Coefficient - Roughness coefficient used in Kutter’s Formula.
Label - A label is the reference by which an element will be referred to in reports, error messages, tables,
etc. It is the unique "name" for your element.
Length - Distance from one end of the pipe to the other end of the pipe.
Loading Pattern - A series of multipliers over time which when applied to a single base load generate a
hydrograph load.
Local Diverted Flow - Flow entering a gravity node that was diverted to that node from another node in
the same network.
Local Infiltration - Infiltration entering the pipe as defined in the infiltration and rate sections.
Local Total Infiltration - Sum of the additional infiltration and local infiltration.
Log Axis Scaling - Compresses the values on the X and/or Y axis to the nearest power of 10. The
numbers shown on the axes are common logarithms of the given variable.
Manning's Coefficient - Roughness coefficient used in Manning’s formula.
Material - The material field is for selecting the pipe's construction material. This material will be used to
determine a default value for the pipe's roughness.
Matchline Offset - Used to design invert elevations in and out of a gravity structure. The specified value
will produce a corresponding drop between the upstream pipe invert elevations and the downstream pipe
invert. A drop such as 0.1 ft is typically used to compensate for the junction headloss. This drop is
applied either at the crown or at the invert of the pipes, depending on the pipe matching option you
selected (crowns or inverts).
Maximum Discharge - The maximum theoretical discharge that could occur for a closed channel using a
given hydraulic computation method. For closed circular channels, this discharge occurs at 0.938 x
Diameter. Any increase in depth will decrease the discharge, which is why the full flow discharge is less
than the maximum discharge for a circular channel. For a detailed explanation of this effect, see Ven Te
Chow’s Open-Channel Hydraulics.
Maximum Extended Operating Point - This point is the absolute maximum discharge at which the
pump can operate, adding zero head to the system. This value may be computed by the program, or
entered as a custom extended point.

326

Glossary

Maximum Operating Point - The maximum operating point of a pump is the highest discharge for
which the pump is actually intended to run. At discharges above this point, the pump may behave
unpredictably, or the pump's performance may just decline rapidly.
Minor Loss Coefficient - Coefficient K used in the equation below, which is the equation most
commonly used for determining the headloss in a fitting, valve, meter, or other localized component:

hm = K
Where:

V2
2g
hm =

Loss due to the minor loss element (m, ft)

V =

Velocity (m/s, ft/s)

g =

Gravitational acceleration (m/s², ft/s²)

K =

Loss coefficient for the specific fitting

Mouse Buttons - The left mouse button is the primary button for selecting or activating commands.
The right mouse button is used to activate (pop up) context menus and help.
Mouse button functions can be re-defined using the Windows Control Panel.

Normal Depth - For a prismatic channel section under a given constant discharge, the depth of flow that
results for a specific channel slope. In subcritical flow conditions, the normal depth is greater than the
critical depth. In supercritical flow conditions the normal depth is less than the critical depth.
Number of Sections - Number of parallel pipes of the same size and type.
Object - An icon on the tool palette that represents an element, such as a pipe, outlet, or junction in a
drawing.
ODBC - ODBC (which stands for "Open Database Connectivity") is a standard programming interface
developed by Microsoft for accessing data in relational and non-relational database management systems
(DBMS’s).
OK Button - When you click on this button the command chosen is carried out or modifications to data
in dialog boxes are subsequently stored.
On/Off Status - The status of a pump can be either on or off. On means that flow will occur in the
downstream direction, and the pump will add head to the system according to it's characteristic curve. Off
means that no flow will occur, and no head will be added.
Open Channel - A channel with a free top surface.
Open/Closed Status - The status of a pipe can be either open or closed. Open means that flow can occur
in either direction. Closed means that no flow will occur through the pipe.
Opening Area - Area of the orifice opening.

Glossary

327

Outflow - Calculated flow being pump out of the wet well.
Overflow Diversion Target - Flow diverted out of an element can be transferred to another element in
the system or lost from the system. Overflow indicates that the flow diverted out of the element is lost
from the system.
Patterns - See Loading Patterns.
Pattern Loads - A type of load that consists of a single base load and a loading pattern that describes
how that load varies over time.
Percent Full - Used in closed channels as a measure of flow depth divided by maximum depth.
Piezometric Height - Height that liquid rises to in a piezometric tube installed at the centerline of a
closed channel.
Pipe Crown Elevation - Elevation of the crown of the pipe calculated as pipe invert elevation plus the
height or diameter of the conduit. Also called crown (or soffit).
Pipe Invert Elevation - Elevation at the bottom of the pipe or channel.
Point - To move the mouse until the pointer on the screen is where you want it to rest.
Population Equivalent - Count of adjusted population for each loading unit of the load.
Power - A pump's power represents the water horsepower, or horsepower that is actually transferred from
the pump into the water. Depending on the pump's efficiency, the actual power consumed (brake
horsepower) may vary.
Pressure - Pressure measured at the specified elevation of an element.
Pressure Head - Energy due to the pressure of a liquid. For open channel flow, this value is zero.

p
γ
Where:

p =

Pressure (Pa, psi)

γ =

Specific weight (N/m³, lb/ft³)

Profile Description - Specifies the type of flow profile in the pipe (such as S2 curve, M1 curve, etc.).
Pull-down Menu - A menu of available commands or actions you can carry out. A pull-down menu is
usually selected from the menu bar at the top of the main program window.
Pumped Flow - Portion of the total flow that comes from a pump located in the upstream network.

328

Glossary

Pump Status - A pump can have two different status conditions: On (normal operation), Off (no flow
under any condition).
RDBMS - An acronym, which stands for Relational Database Management System.
Relative Speed Factor - The pump's relative speed factor defines the characteristics of the pump relative
to the speed for which the pump curve was entered (in accordance with the affinity laws). A speed factor
of 1.00 would indicate pump characteristics identical to those of the original pump curve.
Reynold's Number -

Re =

4VR
ν

Where:

ν =

kinematic viscosity (m²/s, ft²/s)

R =

hydraulic radius (m, ft)

Re =

Reynold’s number

V = velocity (m/s, ft/s)
A high Reynold's number (larger than 4000) indicates turbulent flow, while a low one (between 0 and
2000) indicates laminar flow. The range 2000-4000 corresponds to a transitional regime.
Rim Elevation - The top elevation of a manhole structure. This elevation is typically flush with the
ground surface. In some cases, the rim elevation may be slightly below the ground surface elevation
(sunk) or slightly above the ground surface elevation (raised).
Roughness - The roughness coefficient based on the roughness method used.
Roughness Coefficient - Roughness value for the channel or pipe. With the exception of the Manning’s
Roughness Coefficients, the default values used are estimates. Most numbers that we show can be traced
to literature; however, the values shown for methods other than Manning’s are Haestad Method’s
estimates. Little information is available for these values and engineering judgment should prevail.
Algorithm by which a flow hydrograph is transformed to account for the transforming affects caused by the
hydrograph traveling through a conduit or an open channel.
Scientific Notation - Numbers expressed as products consisting of a number between 1 and 10 multiplied
by an appropriate power of 10.
Section - A cross section perpendicular to the flow through a channel or pipe.
Section Shape - The section type or geometric shape of the pipe. Haestad Methods supports circular
pipes, box pipes, arch pipes, horizontal and vertical ellipses.
Select - To click the mouse button while pointing the cursor at an element in a list or at a command
button.
Service Area - Total area contributing to sanitary loads at a node. The contributing area is specified
through area-based unit sanitary load.

Glossary

329

Shaping Adjustment - Adjustment coefficient used in the AASHTO equation for structure headloss
calculation (refer to the equation in the Help) to account for partial diameter structure shaping (equivalent
to Half and Full in HEC-22). If structure shaping is used then the headloss is decreased by this factor
(50% default).
Shortcut Keys - Combination of keys allowing you to carry out menu commands instead of using the
mouse.
Shutoff Point - The shutoff point is the point at which the pump will have zero discharge, and is typically
the maximum head point on a pump curve.
Size - Inside diameter of a pipe section for a circular pipe. Dimensions of a box section or pipe arch
(width x height).
Slope - Longitudinal slope in the channel. Non-uniform flow may have two types of slopes: friction slope
and construction slope.
Specific Energy - Sum of the elevation head and velocity head as related to the section of a channel bed.

E=Y+

Where:

V2
2g
g =

gravity (m/s², ft/s²)

V =

velocity (m/s, ft/s)

Y =

depth (m, ft)

Specific Weight - The weight of a unit volume of a substance.
Standard Headloss Method - The Standard Method estimates headloss through junction chambers or
manholes of a sanitary sewer system. See Headloss Coefficient - Standard Method.
Station Number - Station numbers are calculated from the network outlet, moving upstream along the
pipe lengths. The Station Number format is specified by right clicking in the Station Number field and
selecting Station Number Properties.
Status Line - The pane at the bottom of the window that shows information such as the coordinates for
the current location of your cursor and the toolbar command being used.
Steady State Analysis - A calculation type where the model is analyzed for a single instant in time. See
also Extended Period Simulations.
Sump Elevation - Elevation of the bottom of a manhole or outlet structure.
Sub Menu - A Sub Menu is a list of related options that is typically reached by selecting a pull-down
menu item.
Sump - Elevation at the lowest point in a manhole or outlet structure.

330

Glossary

System Additional Infiltration - Cumulative additional infiltration resulting from the upstream pipe
network.
System Infiltration - Cumulative infiltration resulting from the upstream pipe network.
System Total Infiltration - Cumulative total infiltration resulting from the upstream pipe network.
Table Links - A table link must be created for every database table (or spreadsheet worksheet) that is to
be linked to the model. Any number of Table Links may reference the same database file.
Tailwater Elevation - Water elevation downstream of the outlet.
Task List - A list of all the applications that you are currently running in Windows. The Task List lets
you switch among applications, rearrange their windows, or quit them altogether.
Tick Interval - Distance between ticks on a graph.
Top Width - Length of the "free" top surface on the flowing cross section. For a cross section flowing
full, this value is zero.
Total Adjusted Population - Non-population-based sanitary loads can be peaked by population-based
extreme flow factor methods using Adjusted Population. Adjusted Population is specified based on
Population Equivalent defined in a non-population-based unit sanitary load. It is a product of total nonpopulation loading unit count and Population Equivalent.
For example, ‘Industry ABC’ defines unit sanitary loads as a function of unit service area in
hectares. For each unit service area Population Equivalent is 1000 capita. If a node has service
area of, say, 25.3 hectares then the equivalent population used for peaking of this load is 25,300
capita.

Total Base Load - Total base load is the sum of base loads of all sanitary loads in the sanitary load
collection. Base load represent the average sewer sanitary load before it is transformed (peaked) using an
extreme flow factor method.
Total Diverted Flow - The sum of the global and local diverted flow entering a gravity node.
Total Flow - Total Flow at the structure going through an element of the network.
Total Population - Population resulting from loads that are population based.
Total Sanitary Flow - Total Flow at a node resulting from sanitary sewage generated during dry weather
from the network upstream of a given node.
Total Wet Weather Flow - Total Flow at a node resulting from the intrusion of rainfall water into the
sewer system from the upstream network. Wet weather load consists of groundwater infiltration and
rainfall inflow. Groundwater infiltration occurs in gravity pipes while inflows occur at manholes and wet
wells.

Glossary

331

Uniform Flow - Equilibrium flow for which the slope of total energy equals the channel slope.
Unit Sanitary Load - Loading unit count representing the local count of loading units for a specified unit
sanitary load.
Unit Load - Sewage flow generated by one loading unit.
Units - Type of measurement displayed in worksheets, rating tables, curves, and cross sections.
User Specified Tailwater Elevation - A tailwater condition that typically occurs when the collection
system discharges to a pond or other receiving body of water whose water surface elevation is greater
than the pipe’s crown elevation. he tailwater elevation for the network can be specified directly in the
Tailwater Elevation field. Although it is typically greater than the crown elevation, it can be any value.
Velocity - Linear measure of flow rate given in units of length/time.
For weir and orifices, the velocity field is for the velocity of the water through the hydraulic
structure.

Velocity Head - Energy due to the velocity of a liquid:

V2
2g
Where:

g =

acceleration of gravity (m/s², ft/s²)

V =

velocity (m/s, ft/s)

Viscosity - Property measuring the fluid resistance to shear. Molasses and tar have relatively high
viscosity and water and air have relatively low viscosity.
Water Elevation - Elevation of the water surface, also called the hydraulic grade in open channel flow.
Water Surface Elevation - Elevation of the channel's flowing surface, usually given in mean sea level
(MSL).
Weight - The mass of a substance times the gravitational acceleration.
Wetted Perimeter - Perimeter of flow that travels against a solid boundary. For a partially full pipe, the
wetted perimeter includes all of the flow perimeter except for the top segment, which has a "free" surface.
X Coordinate - Coordinates are distances perpendicular to a set of reference axes. Some areas may have
predefined coordinate systems, while other coordinate systems may be arbitrary.
Coordinates may be presented as X and Y values, or may be defined as Northing and Easting values
depending on individual preferences.

332

Glossary

Y Coordinate - Coordinates are distances perpendicular to a set of reference axes. Some areas may have
predefined coordinate systems, while other coordinate systems may be arbitrary.
Coordinates may be presented as X and Y values, or may be defined as Northing and Easting values
depending on individual preferences.

References

333

References
AASHTO Model Drainage Manual, American Association of State Highway and Transportation Officials, 1991.
American Society of Civil Engineers, Gravity Sanitary Sewer Design and Construction. American Society of
Civil Engineers, New York, 1982.
Benedict, Robert P. Fundamentals of Pipe Flow. New York: John Wiley & Sons; 1980.
Brater, Ernest F.; King, Horace Williams. Handbook of Hydraulics. New York: McGraw-Hill Book Company;
1976.
Brown, S.A., S.M. Stein, and J.C. Warner, Urban Drainage Design Manual. Hydraulic Engineering Circular
No. 22, U.S. Department of Transportation, Federal Highway Administration, Washington, D.C., 1996.
Chow, Ven Te. Open-Channel Hydraulics. New York: McGraw-Hill Book Company; 1959.
Computer Applications in Hydraulic Engineering. Third Edition. Haestad Press: Haestad Press; 1999.
CulvertMaster User’s Guide. Connecticut: Haestad Methods; 1998.
D. Earl Jones, Jr. Design and Construction of Sanitary and Storm Sewers. ASCE Manual of Practice, No. 37;
1970.
Essential Hydraulics and Hydrology. Connecticut: Haestad Press; 1998.
Featherstone, R.E.; Nalluri, C. Civil Engineering Hydraulics. New York: Granada.
FlowMaster PE User’s Guide. Connecticut: Haestad Methods; 1998.
French, Richard H. Open-Channel Hydraulics. New York: McGraw-Hill Book Company; 1985.
Practical Guide to Hydraulics and Hydrology. Connecticut: Haestad Press; 1997.
Hwang, Ned H. C.; Hita, Carlos E. Hydraulic Engineering Systems. New Jersey: Prentice-Hall, Inc.; 1987.
Hydraulic Research Station, Velocity Equations for Hydraulic Design of Pipes, Metric Edition, HMSO, London,
1951 (10/81).
Hwang, Ned H.C. and Hita, Carlos E., Hydraulic Engineering Systems, Prentice-Hall Inc, New Jersey, 1987.
Roberson, John A., John J. Cassidy, and Hanif M. Chaudhry, Hydraulic Engineering, Houghton Mifflin
Company, Massachusetts, 1988.
Roberson, John A. and Clayton T. Crowe, Engineering Fluid Mechanics (4th Edition), Houghton Mifflin
Company, Massachusetts, 1990.
Simon, Andrew L., Practical Hydraulics, John Wiley & Sons, Inc, New York, 1976.
Singh, V.P., Hydrologic systems, Volume I.- Rainfall-runoff Modeling. Prentice Hall, New Jersey, 1988.
Streeter, Victor L. and Wylie, E. Benjamin, Fluid Mechanics, McGraw-Hill Book Company, New York, 1985.
Todini, E. and S. Pilati, "A Gradient Algorithm for the Analysis of Pipe Networks", Computer Applications in
Water Supply, Volume 1 - Systems Analysis and Simulation, ed. By Bryan Coulbeck and Chun-Hou Orr,
Research Studies Press LTD, Letchworth, Hertfordshire, England.
Tchobanoglous, George, Wastewater Engineering: Collection and Pumping of Wastewater, McGraw-Hill, Inc,
1981,

334

References

Zipparro, Vincent J. and Hasen Hans, Davis’ Handbook of Applied Hydraulics, McGraw-Hill Book Company,
New York, 1993.

Index

335

Index

Known Flow

135

Manager

128

Manager Dialog

A

21

Operational

139

Physical

130

Sanitary Loading

133

Structure Headlosses

135

User Data
AASHTO

99, 258

139

Analysis Results Report

Bend Angle and Loss Section

150

Analysis Toolbar

Bend Loss

264

Annotation

Bend Loss Original Equation

264

Comparison Wizard

Calculation Options

150

Multipliers

Coefficients

150

Size

24, 171
28
24, 53, 55, 167, 168
184
67
235

Contraction Loss

263

Annotation Properties

168

Correction For Non Piped Flow

265

Annotation Tab

178

Correction for Shaping

265

Annotation Wizard

Expansion Loss

265

Arch Section
Area

168
192, 193

Headloss - AASHTO Method

263

Headloss Method

150

Enclosed by Polyline

Shaping Method

317

Flow

Abbreviated Labels

124

Area-Based Unit Sanitary Load

197

Absolute Headloss

317

ASCII Loading Data Format

296

ASCII Loading File Example

301

Assumptions

260

Absolute Method
Absolute Roughness
Add

99, 258, 259
317
74

77
322

Attribute

Bends in AutoCAD

230

Annotation

167, 168

Junction Chambers

74

Inheritance

308

New Elements

74

Auto Prompting

Outlets

74

AutoCAD

Pipe Run

222

Command Line

Pipes

74

Commands

Pressure Junctions

74

Drawing Synchronization

Pumps

74

DXF

74

Element Scale

Wet Wells

65
183
16, 17
230
228
223, 224
229

Add New Load Dialog

111

Entities

Advanced Options

110

Exporting DXF File

223

Adverse Slope

251

Import SewerCAD

232

Importing DXF Files

224

Importing SewerCAD DXF Files

224

Proxies

233

105

Rebuild Figure Labels

227

281

Right Click Context Menu Option

Aerial View

80

Affinity Laws

268

Allow
Multiple Sections Section
Allow Multiple Sections
Alternatives

45-49, 127, 128, 133, 136, 144, 306

Boundary Conditions
Children
Design Constraints
Editor

136
45
136
129, 140

Undo/Redo
AutoCAD Mode

225, 226

65
231
13, 225

Graphical Layout

226

Project Files

227

Toolbars

226

Infiltration and Inflow Loading

134

AutoCAD Mode Window

Inheritance

308

AutoCAD Sessions

Initial Settings

138

Autodesk

13
63
225

336

Index

Autodesk Civil Design Export
Automatic Design

221

21, 43, 104, 147, 280, 285

AASHTO

150

HEC-22

149, 150

Hydrographs

285

Calculation Options Generic Structure Loss

150

Pattern Loads

285

Calculation Type

147

Automatic Element Labeling

223

Calculations

Available in Materials

194

Cancel Button

Average Velocity

149, 255, 256, 317

Weigthed
Average Velocity Methods

255
255

B

144, 148, 244
317

Capacity

317

Analysis

256, 257

Full Flow

323

Capacity Analysis

147

Capital Cost Reports

164

Change
Column Label

Background Drawing
Background DXF (AutoCAD)
Backwater Analysis

223
223
147, 254

223

Entities to Pipes

19, 232

Channel
Closed

318

Barrels

326

Invert

318

Base Load

317

Open

326

Slope

318

Base Load Dialog

112

Base Scenarios

139, 140

Check Valve

Batch Run

139, 141

Chezy's Equation

Benching Correction
Bend Angle
Bend Loss

262
96, 150, 317
150, 264

Child

Classification

Coefficient

317

of Profiles

Adding in AutoCAD
Bibliography
Blocks (AutoCAD Mode)
Bolted Cover

139, 140, 307, 309, 310

Circular Section

264

Bernoulli Equation

308

Scenario

AASHTO
Bends

318
246, 247

192, 194
251

Slope
230
244, 321
333
217, 224
90, 317

250, 251

Clipboard
Copy Table

126

Copy to

29

Closed Channel

318

Coefficient

Borders

185

Boundary Conditions

105

Coefficients

287

Boundary Conditions alternative

136

Kutter's n

325

192, 193

Manning's

325

Roughness

328

Box Section
Button
Cancel
Help

317
25

Mouse

326

OK

326

AASHTO

150

Colebrook-White
Equation

248

Typical Values
Color Coding

291
24, 56, 169, 170, 186, 235, 236

Column

C
C Coefficient
Calculate Network
Calculated Hydraulic Grade
Calculated Hydraulics Section

249, 317
21, 33, 147
317
94

Calculation
Problem Summary Report
Results Status
Calculation Options

173
31
148, 150

Allow Duplicate

120

Change Units

236

Heading

124

Table Customization

124

Table Setup

119

Command Line (AutoCAD Only)

16

Commands (AutoCAD Mode)

230

Compare Scenarios

184

Composite Capacity Profile

256

Composite Inflow Dialog

135

Composite Loading Dialog

133

Index

337

Composite Minor Loss

97

Configuration

64

Conjugate Gradient Method

Shaping - AASHTO

273

Connection

199, 200

Database

265

Cost

203, 204

159

Alternative

139

Analysis

159

Manager

159

Editing

203

Cost Manager - Button Section

Hiding

207

Cost Manager - Center Pane

160

Management

201

Cost Manager - Left Pane

161

Missing

207

Cost Tab

109

Shapefile

210

Cost Warnings Report

165

Count-Based Unit Sanitary Load

197

Cover

318

Coveyance Element

318

Sharing

207, 208

Connectivity Tolerance

218

Conservation
of Mass & Energy

270

160

Create

Constant Increment Hydrographs

298

New Elements

Constant Increment Patterns Section

296

New Project

26

Creating Scenarios

142

Constant Power Pump

93, 269

Constants

74

Critical

Gravitational
Constraint Based Design
Constraints

323

Depth

104

Depth and Slope

21, 104, 286

Warning Messages

286

250, 319

Slope

251, 319

318

Construction Costs

110

Construction Costs Table

110

Context Menu

318

Matching

65

Crown Elevation

Context Menu Option

Crosshair

AASHTO

263, 264

30

Crown

319
282

Pipe

327

CulvertMaster

316

Cursor

319

Control Condition

102

Cursor Location

Control Preview

102

Curve

Control Status

318

Control Symbols

319

Location

318

Contraction Loss

250

Flow

Constructed Slope

Contraction

318

Pump

30
93, 94, 267, 268, 269

Custom AutoCAD Entities

225

Visibility

227

Custom Extended

269

Control Type

102

Custom Sort

123

Controls

102

Customization

Converting Native AutoCAD Entities
Convex Routing
Convex Routing Tab

231

151, 274, 275

Drawing

227

Customize

151

Coordinate

Database

201

Drawing

67, 68, 69

X 66, 331

Labels

124

Y 66, 332

Libraries

189

Tables

124

Copy to Clipboard

29

Table

126

Copy/Paste

19

Cut
Cutoff Value

19
319

Correction for
Benching

262

Flow Depth

261

Non Piped Flow - AASHTO

265

Pipe Diameter

261

Plunging Flow

261

Colebrook-White Equation

Relative Flow

261

Equation

D
Darcy Weisbach
248
247, 248

338

Index

Roughness Values

291

Discharge

Data
Entry

308, 309

Data Entry

33, 113

Data Organization

127

Data Structure

127

Database

199, 200

Export

201, 202, 203

Import

202, 203

320

Junction

324

Known

324

Maximum

325

Outlet
Discharge-Based Unit Sanitary Load
Display Precision

90
197
70, 320

Display Tips
Change Units in a Column

236

Color Code Elements

235

206, 207

Control Element/Label Sizing

235

Synchronization Options

204

Reuse Deleted Element Labels

235

Table Link Editor

204

Database Connection

199, 203, 204, 319

Management Systems

319

ODBC

Diversion

320

Diversion Network

183

Editor

203

Diversion Network Background Color

184

Example

208

Diversion Network Options

184

Manager

201

Diversion Network Window

183

ODBC

207

Diversion Parameters

Standard

201, 202, 203

Diversion Rating Curve Table

101
101, 320

DBMS

319

Diversion Tab

100

Default

113

Diversion Target

320

Design Constraints
Default Design Constraints
Default Kinematic Viscosity
Delete

104, 105, 157
21, 44, 157
288
19, 20

Elements

Double-click
Drafting
Drag

320
77, 185
320

Drawing

77, 229

Options

63, 64, 67

Runs

223

Pane

Table

118

Preview

220

78

Review

80, 81, 217

Delete Selection Set
Demand

Scale

Multipliers

154

Depth

319

Critical

250, 318

Flow
Design

322
43-45, 104-105, 157, 280-282

15

67

Setup (AutoCAD Mode)

227

Synchronization (AutoCAD Mode)

228

Drawing Tab
Drop Structures
Sanitary (Dry Weather) Loading

178
283
239, 241

Considerations

287

Duration

Constraints

105

DWG

63, 227

Default Constraints

157

DXF

68, 223

Drop Structures

283

Background

Extended

157

Exporting from SewerCAD

224

Limit Section Size

282

Import

223

Import Techniques

224

Menu

21

320

30, 68

Part Full

281

Priorities

283, 285

Dynamic Inheritance

307, 308

286

Dynamic Parameters

178

Design Considerations
Design Point
Desired Sump Depth
Detailed Report
Diameter
Correction
Direct Step Method
Direction of Flow
in Gravity and Pressure Systems

Units

68

93, 269, 320
320
24, 171

E

320
261
253

Edit
Controls
Gravity Pipes

276

Junction Chambers

102
88
86, 87

Index

339

Manholes

86

Energy Grade Line

Outlets

88

Energy Slope

Pipe Run

222

321
321

Engineering Library

189, 190, 191

Pressure Junctions

88

Available Materials

194

Pumps

87

Editor

190

Wet Wells

87

Extreme Flow Factor Method

191

Edit Elements

229

Manager

189

19

Material

Edit Menu
Editable Table Columns
Editing Elements
EGL
Element
Annotation
Delete Bend (AutoCAD Mode)
Deleting
Editing
Find
Insert Bend (AutoCAD Mode)
Labeling
Modify
Morphing

121, 122
76
245
85, 229, 320
167
19
77, 229
19, 86, 229
78, 79
19
83, 223, 235
229
74

Moving

77, 230

Numbering

82, 235

Rotate (AutoCAD Mode)
Scale (AutoCAD Mode)
Search
Selection
Type

19

Section Size

192
287

Enter Key Behavior

64, 65

Entities
Change to Pipe

232

Entities in AutoCAD

225

Entity Conversion

232

Equation
Bernoulli

321

Chezy

246

Kutter's

246

Equations

287

Error Messages
Results Report

145

ESRI

199, 200, 215

19, 229

Export Shapefile

213

78

Import Shapefile

211

Shapefile Connection

210

75, 76, 77, 83
74, 75

Example Projects

164

Element Graphing Report

173

Excess Capacity Profile

228

Exit Discharge

Elevation

195, 196

Engineer's Reference

Element Detailed Cost Report
Element Properties

195

Minor Loss

103, 320

Tutorials

10
256, 257, 258
321

Exit SewerCAD

19

Ground

323

Exit Velocity

321

Invert

324

Exit Velocity Head

321

Mode

66

Expansion

321

Pipe Crown

327

Pipe Invert

327

Rim

328

Explode Elements (AutoCAD Mode)

Water

331

Export

Water Surface

331

Elliptical Section

192, 194

Expansion Loss
AASHTO

Database

265
18
18, 19, 201, 202, 203

DXF

Email Address

11

Land Development Desktop

Enclosed Area

77

Profiles in AutoCAD

Energy

230

17, 223
18
183

320

Runs

Balance

252

Shapefile

Conservation

270

Shapefile Link Editor

214

Discontinuity

286

Structure Mappings

223

Equation

245

Table to ASCII

126

Grade Line

245

to Autodesk Civil Design

221

Loss

149, 150

222
18, 19, 213, 214

Extended Period Section

148

Principle

244

Extended Period Simulation EPS

321

Specific

329

Extended Period Simulations Overview

274

286

Extension

321

Energy Discontinuity

340

Index

External Files

321

FlowMaster

Extrapolate

322

Format

Extreme Flow Factor

33, 241, 242

User Data

316
70
114

Equation Properties

191

Formulas

287

Method

191

Free Outfall

254

Table Properties

192

Friction Factor

322

156

Friction Loss Methods

245

156

Friction Method Theory

Extreme Flow Setup
Manager

Friction Slope
Frontwater Analysis

F
Factor
Extreme Flow
Friction
Relative Speed
Variable Peaking
Fax Number

323

Full Capacity Profile

256

Full Flow

323

322
94

Capacity

323

Slope

323

Velocity

255

242
11

G

Links

205

Share

116, 117
322

General Information

89, 91

General Section

89, 91

General Status Information

File
Export Settings

222

Global Diverted Flow

File Management

63

Global Edit

File Menu

17

Global Options
Globe Button

Files
AutoCAD

227

Glossary

Filter Tables

123

Go Button

Find Element

19, 78, 79

Fitting Loss Coefficients

266

Fittings Library

195

FlexTables
FlexUnits

254, 255

Froude Number

241, 242

Field

Field Links

66
322

30
323
122
64, 65
6
10
147

Grade
Hydraulic

324

Grade Line

40, 41, 117

Energy

321

69, 70

Energy

245

Table

71

Hydraulic

324

Flooding

254

Hydraulic

245

Flow

322

Gradient Algorithm

322

Critical

250

Gradually Varied Flow

250

Depth

322

Direct Step Method

253

Depth Correction

261

Standard Step Method

253

Full

323

Known

324, 325

Derivation

270

Area

Graph Options
Graph Setup

Pressure

249

Graphic Annotation

Regime

249

Graphical Editor

Subcritical

250

Graphical Layout

Supercritical

250

AutoCAD
Stand-Alone

Surcharged

249

Type

322

Gravity

Uniform

331

Gravity Hydraulics Tab

Flow Diverted In

101

Gravity Pipe

Flow Diverted Out

101

Add

Flow Profile Methods

149

Default Design Constraints Section

271

176
173, 174
22, 185
73
226
73
323
148
88, 89
74
157

Index

341

Infiltration/Inflow Loading

134

Structure

Gravity Pressure Interface Options

152

HGL Mode

Gravity Structure

194

Horizontal Slope

251

137, 138

Gravity Structure Tab

158

Horse Power (Pump)

Gravity to Pressure Network Transition

277

How Do I

Ground Elevation

323
75

Selection Sets

77

93
9, 25, 235, 236

Profile Plot

236

Share Database Connections

207

How to Use Help
Hydraulic Grade Line

H

66

Horizontal Section Size Properties

Design Constraints

Grouping Elements

324

25
245, 323, 324

Hydraulic Jump

103

Hydraulic Radius

324

Hydraulic Results Section
Haestad Methods
Haestad Methods Knowledge Base
Haestad Methods Workshops
Hastad Methods Software

5, 11

Hydraulic Time Step

237

Hydraulic Transition

98
276, 324

10

from Gravity to Pressure Network

277

315

from Pressure to Gravity Network

278

CulvertMaster

316

Hydraulics Options

149

FlowMaster

316

Hydrograph

324

PondPack

316

Hydrograph Dialog

SewerCAD

315

Hydrographs

173, 240
276, 324

112

StormCAD

316

Hydrologic Time Step

WaterCAD

315

Hydrologic vs. Hydraulic Time Steps

Hazen Williams Equation

276

249

Coefficients

293

Roughness Values

292

I

Pressure

327

Identifying Gravity Pipes and Force Mains

Velocity

331

Import

Head

Headloss

149, 150, 259, 323
195

DXF

259

DXF Files into AutoCAD

Headloss Coefficient

323

Land Development Desktop

289

Polyline to Pipe

323

SewerCAD

Coefficient

Manholes and Junctions
Headloss Gradient
Headloss Method

18
224
17
18
18, 19, 232

Shapefile Link Editor

212
295

99, 258, 259

Importing Loading Data Overview

295

99, 259, 260

Include In Cost Calculation

109

Infiltration

243

100, 258, 263

Absolute
HEC-22 Energy
HEC-22

201

Import Loading Data Dialog

99, 149, 150, 258, 323

AASHTO

Standard

18

Database

Headloss - Generic Method

276

100, 258, 259
99, 149, 258, 259, 260

Additional

108

Benching Method

323

Direct

108

Energy Loss Method

323

Local

109

System

Height
Piezometric
Help
How Do I

327

Infiltration and Inflow Loading

109
108, 109, 243

Infiltration and Inflow Loading Alternative

134

9

Infiltration Hydrograph

108

9, 10, 25, 26, 33, 235

Technical Support

11

Infiltration Pattern Load

108

Tutorials

10

Infiltration Tab

108

Help Button

25

Infiltration Type and Rate Sections

Help Menu

25

Inflow

HGL
Above Ground / Rim

245, 323
254

108
243, 324

Inflow Loading
Structure

135

342
Inflow Section
Inheritance

Index
107
307, 308

Known Loading

239, 243

Known Loading Alternative

135

Dynamic

308

Kutter Formula

290

Overriding

307

Kutter's Equation

246

Initial Headloss Coefficient

260

Initial Settings
Pressure Pipe

138

Pump

138

Wet Well

139

Initial Settings Alternative

n Coefficient

325

Roughness Values

290

L

138
Label

Initialize

325

223

Abbreviate

76

Automatic

84

Elements

Input Data

85

Rotate

230

Input Modes

66

Sizing

235

Run List
Input
Quick View

Insert

124
223
83, 235

Label Rebuilding (AutoCAD Mode)

227
178

Elements

75

Labels Tab

Nodes

75

Land Development Desktop

Installation Guide for
Network License Versions

Export Wizard

222

7

Import Settings

221

Installation Problems

4

Import Wizard

220

Installing Haestad Methods Products

4

Unit System

222

Internet Address
Interpolate

11
324

Interval
Tick
Inventory
Invert

Laws
Affinity
Conservation of Mass & Energy

330
50, 172
324

Layer
Layers Tab
Layout

Channel

318

AutoCAD

Matching

282

Network

Invert Elevation
Pipe
Inverts and Sizes

96, 324

73

Layout Pipe Using Entity

232

280

Left click
Quick View

289, 324

Flooding

254

Headloss Coefficients

289

Lesson 5 Running an Extended
Period Analysis
Lessons

328
24, 185, 186
84
325
56
33, 43, 55

Automatic Design

43

23

Creating a Schematic Network

33

74

Presentation of Results

50

Scenario Management

45

Junctions
Headloss Coefficients

226

327

Length

Add

178
33-35

178

J

Junction Chamber

270
220, 229

Layout Options Tab

Legend

Junction

268

289

Level Mode

66

Library

K

Editor

190

Manager

190

Material

195

195, 266

Minor Loss

195

Kinematic Viscosity

324

Library System

Known Discharge

324

Extreme Flow Factor Method

191

Known Flow

324

Section Size

193

K Coefficients

Index

343

Licenses

5

Limit Section Size

Shortcut Keys

105, 282

Line

185

Enclosed Area

77

16

Toolbars

16

Tools

22, 24

Messages

111

Linear System Equation Solver

273

Metric

Linear Theory Method

270

Microstation

223

Mild Slope

251

Link Color Coding

170, 235

List

64, 70

Minimum

Task

330

Loading

37-39, 41, 196, 197, 239, 243

Dry Weather

239

Known

239, 240, 243, 244

Wet Weather

239, 240, 242, 243

Loading Pattern

325

Allowed Value

70

Minimum Structure Headloss

149

Minimum System Requirements

3

Minor Losses

266

Coefficient

Local

326

Fitting

267

Properties

195

Addional Infiltration

317

Mix Units in a Tabular Report

125

Infiltration

325

Mixed Flow Profiles

253

Units

125

Mode

Local Diverted Flow

325

Input

66

Local Infiltration

109

Scaled

67

Log Axis Scaling

325

Schematic

67

Loss and Bend Angle Section

150

Stand-Alone/AutoCAD

13

Losses
Minor

266

Model

85

Morphing Elements

74

Move
Elements

M

76, 77, 230

Labels

231

Multiple
Mailing Address

11

Pump Curve

Manager

Units

Extreme Flow Setup

156

Manholes

22, 86

Add

Multiple Sessions

63

Multipliers

67

74

Mannings Equation

246

Manning's Coefficient

325

Roughness Values

290

Typical Values

N

293

Native AutoCAD Entities Converting

Mass Conservation

270

Network Deployment Folder

Match Pipes

282

Network Licensing

Matchline Offset

282, 325

Material

195, 325

Library
Maximum Discharge

9
6

New

17, 18

Project

26

New Elements

74

325

Node

93, 325

Maximum Operating Point

93, 326

Context

217, 231

195

Maximum Extended Operating Point
Menu

269
125, 126

16, 17, 19, 20, 22, 24, 25
318

Color Coding

170, 235

Non-Construction Costs

110

Non-Population Based Unit Sanitary Load
Normal Depth

196

249, 326

Design

21

Northing Easting Mode

Edit

20

Notation

File

17, 18

Scientific

328

25

Scientific

70

Help
Options

113

Report

25

66

Number
Froude

323

344

Index
Extended Period Analysis

154

Reynold's

of Digits After Decimal Point

328

69

Pattern Editor

154

Station

329

Pattern Graph

155

326

Time Steps

154

Number of Sections

Pattern Load Dialog
Pattern Loads

O

Pattern Manager
Pattern Setup

Object

326

ODBC

206, 326

Offset Matching
OK Button
On-line Help

Peaking Factor

326

Percent Full

326

Open Database Connectivity

206, 326

Open Project

Patterns

282
9, 25

Open Channel

Pattern Setup Manager

17

Wetted
Phone Number
Physical Properties

326

Junction Chamber

Opening Area

326

Manhole

94

153
155, 156
155
327
156, 242
327

Perimeter

Open/Closed Status
Operating Point Section

112
240, 327

331
11
130
132
131, 132

Pressure Junction

132

Operating Range

106

Pressure Pipe

130

Operational Alternative

139

Pump

132

Wet Well

132

Options

30

AASHTO

150

Pie Charts

176

Calculation

148

Piezometric Height

327

Drawing

67

Global

64

Graph

174, 175, 176

HEC-22

149

Pressure

151, 152

Profiling

181

Project

63, 66

Pipe
Average Velocity
Bends
Controls

255
150
101, 102

Crown Elevation

327

Default Design Constraints

157

Design Constraints

104

Options Menu

113

Diameter Correction

261

Organize Data

127

Elevations

103

Other Factors

150

Exit Properties

100

Outflow

327

Extended Design Section

157

Fittings

195

Outlet

23, 24

Control

254

General Characteristics

Outlets

88

Hydraulic Summary Section

Add

74

Infiltration

Output

167

Invert Elevation

84

Length Rounding

QuickView
Tables
Overflow Diversion Target(Overflow)
Overview

117

Matching

327

Profile

63

P

Pattern

281
152, 153

Demand

96
243
96, 327
66
104, 282
103

Roughness

96

Sizing

95

Splitting

75

Tool

74

User Defined
Part Full Design

95

96

Pipe Costs Report

165

Pipe Layout Using Entity

232

Pipe Run

Multipliers ................................................... 154

Add

222

Pattern ......................................................... 154

Pipe Tool

22

Index

345

Pipes

88

Excess Capacity

Add

74

Full Capacity

256

Plan View

25

Options Dialog

181

256, 257, 258

Plan View Reports

172

Plot

Plot Window

174

Templates Dialog

Plunging Flow Correction

261

Window

180, 181

Point

327

Wizard

179, 180

Polygon Enclosed Area

77

Polyline
Conversion Problem
Enclosed Area
Polyline to Pipe Conversion

220
77

180, 236
177

Profile Background Tab

182

Profile Description

327

Profile Layers

182

Profile Methods Section

217

Profiles Manager

149
176, 177

Wizard

218

Profiling

PondPack

316

Project

Population Based Unit Dry
Weather Load Properties

196

Inventory Report

327

New

26, 27

93, 327

Open

26, 27

Options

63, 66

Population Equivalent
Power

Inventory

Precision
Display

320

Precision Display
Predefined Reports

24, 182

70, 71
170, 171

50
172

Save

26

Setup Wizard

63

Summary

63, 64

Preferences

64

Presentation

167

Project Detailed Cost Report

Preserve Pumped Flows

152

Project Element Summary Cost Report

Pressure

327

Project Files

Head

244, 245

Pressure Flow

249

Free Surface Flow
and Transitional Flow.................................. 260

Title

Project Summary
Project Summary Cost Report

64
165
165
63, 227
17
165

Prototype

63

Prototypes

113

Pressure Head

327

Proxies

233

Pressure Hydraulics Tab

151

Publications

315

Pressure Junctions
Add
Pressure Junctions General Section
Pressure Mode

24, 88

Pull-down Menu

74

Pulldown Menus

95

Pump

66

Pressure Options
Pressure Pipe
Add

151

Add
Affinity Laws

89

Constant Horsepower

74

Curve

138

Definition

Pressure to Gravity Network Transition

278

Initial Settings

Preview

186

Initital Condition

Initial Settings

Print

17, 19, 30

Preview
Preview Window

93
138
94
267, 268, 269
327

186

93

17
4

103, 104, 176, 177, 181, 182, 236

Classification

269
93, 267, 268, 269

Power

126

Axis

74
267

Power

Setup

Profile

17
22, 87, 88

26, 29

Table
Problems with Setup or Uninstall

Operating Point

16

182
251, 252

Drawing Tab

182

Elements Tab

181

Pumped Flow

327

Status

328

Theory

267

Type

269

Variable Speed
Pump Curve

268
93, 94, 267, 268

346

Index
Chezy's Equation

Q

246

Coefficient
Quick Attribute Selector

71

Quick View Window

21

R

Hydraulic
Rapidly Varied Flow

253

RDBMS

328

Rebuild Figure Labels

227

Recent Files

17

Redefine SewerCAD Blocks
Redo

224
19, 30, 231

Reference
Engineer's

287

References

246

Roughness Coefficient

328

Roughness Values

287

82

Relational Database Management System
Relative Flow Correction

328
261

Relative Speed Factor

94, 328

Release Notes

25

Remove
Columns

120

Elements

77

Haestad Methods Products

4

Removing Color Coding from
labels imported from Pre-v3.5 files?
Report Menu

236
24

51, 52, 167

Analysis Results
Detailed

290

Manning's

290

Typical

293
70
66

Routing Overview

274

Running the Model

147

Runs
Delete

223

to Export to Land Development Desktop

222

to Import

221

Project Inventory

24, 172

Scenario

25, 172

Tabular

Sales

24, 172
7
167
80
328

11

Sample Projects

10

Sanitary Dry Weather Flow Section

107

Sanitary Hydrograph Loads Section

299

Sanitary Loading Alternative

133

Sanitary Pattern Loads Section

297

Sanitary Unit Loads Section
Save

228

Project

26
17
67

Elements (AutoCAD Mode)
Scaled Mode

299
18, 19

as Drawing*.dwg

171
170, 171

Requesting Permanent Network License

S

Scale

172, 173

Reynold's Number

292, 293

171

Predefined

Review Drawing

Hazen-Williams
Kutter Formula

Save As

Plan View

Results

291, 292

81

Relabel Operations

Reports

291

Darcy-Weisbach

Pipe Length

5, 25

Relabel Elements

Colebrook-White

Rounding

6

Registration

247
249

333

Registering Network Programs

248

Darcy-Weisbach Equation
Hazen-Williams Equation

324
243

Colebrook-White Equation

Manning's Equation

Radius
Rainfall

195, 290

229
67

Scaling
Log Axis
Scenario
Alternatives

325
139, 141, 142, 184, 306, 307
144

Base

139, 140

Batch Run

141, 142

Child

Right Click Context Menu Option

65

Comparison

Right Mouse Button

65

Editor

307
184
140, 144

Rim Elevation

328

Inheritance

Rotate Labels (AutoCAD Mode)

230

Management

127

Roughness

328

Results

145

317

Selection

140

Absolute

307, 308, 309

Index

347

Summary Report
Scenario
Management

172
21, 45-49, 141, 303, 313

Example

310

Documentation

9

Elements

85

Exploring

13

How to Use it

1

Scenario Wizard

142

Import

232

Scenario Wizard - Step 3

143

Menus

318

Scenarios

45, 46, 48, 49, 50

Alternatives

45

Analysis Toolbar

28

Calculation

144, 145

Children

45

Comparison

45, 49

Management

45

Schematic

33, 34

Schematic Mode

67

Scientific Notation

70, 71, 328

Sealing Conditions

253

Search for Elements

78

Section

328

Toolbars

26

User's Guide

9

SewerCAD in AutoCAD

225

Files

227

SewerCAD Theory

239

SewerCAD VCR Controls

28

SewerCAD Window
Shapefile

13
208, 209, 210, 211, 212

Format
Shapefile Connection

215
208, 209, 210, 211, 212

Editor

209

Example

215

Export Example

214

Materials

194, 195

Export Wizard

213

Section Size

193, 194

Import Example

212

Arch

193

Import Wizard

211

Box

193

Link Wizard

210

Circular

194

Manager

208

Horizontal Ellipse

194

Synchronization Options

212

Wizard

209

Properties

192, 193

Vertical Ellipse
Section Type

194

Shaping Adjustment

329

328

Shaping Method

317

Share Fields

116

Sharing Shapefile Connections
between Projects

215

Sections
Number of

326

Select

23, 328

By Selection Set

19, 77

Element Types
Elements

211
20, 75, 76

Sharing Templates Between Projects

179

Shortcut Keys

16, 329

Shutoff Point

93, 329

Field Links

205

Simple Average Velocity

255

Layer

229

Simultaneous Path Adjustment Method

270

Runs to Import

221

Size

329

Text Style

229

Size Elements (AutoCad)

229

Sizing Pipes

280

Slope

329

Selecting Upstream / Downstream Elements
Selection Set

76

77, 78

Manager
Selection Tool
Service Area

21, 78

Adverse

251

22

Channel

318

Classification

250

328

Set Field Options

69

Constructed

Settings

64

Critical

250, 251

4, 64, 227

Friction

322

Setup

318

Drawing Options

67

Full Flow

323

Global Options

64

Horizontal

251

4

Mild

251

66

Steep

251

Problems
Project Options
Prototypes
SewerCAD

113
1, 25, 26, 315

AutoCAD Custom AutoCAD Entities

225

Snap Menu (AutoCAD Mode)

231

Soffit

319

Software Registration

5

348

Index

Sort

Database Links

Custom

201

123

Error

Sort By Network

123

Options

204

Sorting Tables

122

Via ODBC

207

Sparse Matrix

271, 273, 274

Specific Energy

329

Specific Weight

329

63

Synchronized Units

125

System
International

Splitting Pipes

75

System Additional Infiltration

Stand-Alone Mode and AutoCAD Mode

13

System Cost Adjustments Table

64, 65, 70
330
161

Standard Database Import/Export

201

System Infiltration

Standard Extended

269

System Requirements

3, 4

Standard Headloss Method

329

System Total Infiltration

330

Standard Method

109, 330

99, 100, 258, 259

Standard Step Method
Station Number

253
89, 91, 329

Status

30, 31, 62

Bar

15, 30, 31

T
Table

117, 120, 121

Line

329

Change Units

125

Log

187

Copy to Clipboard

126

Pane

64

Customization

124
118

Steady State Analysis

329

Editing

Steady State EPS Load Method Section

151

Export to ASCII File

Steady State Section

147

Filtering

Steep Slope

251

Flex Units

Sticky Tools

65

StormCAD

316

Stretch

77

Headlosses

254
258, 259

71
330

Manager

117

Mixing Units

125

Navigation

Structure
Flooding

Links

126
123, 124

Print

121, 122
126

Print Preview

126

HGL

324

Properties

119

Sump Elevations

283

Setup

119

Structure Energy Grade

286

Two Rows

118

Structure Headloss Alternative

135

Type

119

Tabular

Structure Mapping
for Civil Design Import

221

Report

for Export

223

Tailwater

Sub Menu

329

Elevation

Subcritical Flow

250

Hydraulics

Suggestions
Sump
Elevation
Supercritical Flow
Support
Surcharged Flow
Surcharging
SWR File

12
104, 329

Symbol Visibility

Task List

283

Technical Support

250

Templates

330, 331
90
331
330
11
177-179

Annotation Tab

178

249

Drawing Tab

178

253

Labels Tab

178

63, 227

Layers Tab

178

11

Symbol
Size Multiplier

User Specified

117

67
69

Layout Options Tab

177

Sharing Templates Between Projects

179

Templates Dialog

177

Text

231

Symbol Visibility (AutoCAD Mode)

227

Synchronize

209

Style

229

228

Text Height

68

AutoCAD Mode

Index

349

How Do I

235

Multiplier

67, 68

Theory

239, 244

Tick Interval

Unit Load
Units

330
256

64, 65, 68, 70, 71, 236, 331
236

DXF

68

Local

125

Time-Based Loading

240

Times Section

300

Updates

T-intersections

219

Upgrades

Title

64, 65, 71

Change in a Column

Time
Travel

331

Unit System

Synchronized

125
5, 26
5

US Customary

65

Project

63, 64

Tolerance

81

Usage

191

Tool Pane

64

User Data

113

Tool Pane Toolbars

26

User Data Alternative

139

Toolbar

16, 226

and Shortcut Keys

16

US Customary Units

64, 70

User Defined Bend Angle Section

96

User Memos

111

Toolbars
Buttons

26

Tools Menu

22

Top Width

330

V
Variable Increment Hydrographs Section

298

Adjusted Population

330

Variable Increment Patterns Section

296

Base Load

330

Variable Peaking Factor

242

Sanitary Flow

330

Variable Speed Pumps

268

330

Velocity

331

Total

Flow
Population
Wet Weather Flow
Total Diverted Flow

330

Full Flow

255

330

Head

245

330

Simple Average

255

Uniform Flow

255

Weighted Average

255

Transition
from Gravity to Pressure Network

277

from Pressure to Gravity Network

278

Travel Time Computation

149, 256

Tutorials

10, 25, 26, 33

Two Row Table

118

Type Coercion

199

Types of Calculation

147

Velocity Head

331

View
Menu
Tabular
Viscosity
Kinematic
Visibility of Symbols

21, 22
117
331
324
227

U
W
Undo

19, 30

Undo/Redo Operations in AutoCAD
Uniform Flow
Velocity
Uninstall
Problems
Unit Conversion

Warning Messages

286

Water Elevation

331

Water Surface Elevation

331

4

WaterCAD

315

4

Weight

331

231
249, 331
255

199

Specific
Weighted Average Velocity

Unit Cost
162

Weighted Translation Routing

Function Formula

162

Welcome Dialog

Function Manager

161

Wet Hydrograph Loads Section

Table Coefficients

163

Wet Pattern Loads Section

Data Table

Unit Sanitary Loads

196, 197, 241, 331

Wet Weather Loading

329
255
275
25, 64
299
297
108, 239, 242

350
Wet Well
Initial Settings
Wet Well Increment
Wet Wells
Add
Wetted Perimeter
What is New in SewerCAD?
White Table Columns

Index
24
152
87

Window Color
Wizards
Annotation Comparison
Polyline to Pipe
Profiling
Project Setup

50

X

74
331
2

X - Y Mode
X Coordinate

66
66, 89, 91, 331

121

Width
Top

WYSIWYG

138, 139

330

Y

65
168, 213

Y Coordinate

66, 89, 91, 332

184
217, 218
180

Z

63, 64

Shapefile Connection

209

Zone Classification

Shapefile Export

214

Zoom

Shapefile Link

210

251
21, 22, 26, 27, 79

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