InfoSWMM 2D Layer Properties and Mesh ID
Subject: InfoSWMM 2D Layer P
You can use the Layer Properties for layers in the Table of Contents to see the Mesh ID and other simulation data for the 2D mesh in InfoSWMM 2D.
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Steady State Flow Analysis in InfoSWMM using a Ramp DWF - Method 2
Subject: Steady State Flow Analysis in InfoSWMM using an External Flow Time Series
Subject: Steady State Flow An
This can be easily created using a few steps in InfoSWMM. The flow ramp is in the Routing Interface File. The advantage is that you are able to have different ramps for the various nodes using this method.
Step 1: In Run Manager Set up the Process Models Options to use just the External Inflow and NOT the Dry Weather Flow
Step 2. Create the External Inflows File (see the help file for the format)
SWMM5 Interface File
300 - reporting time step in sec
1 - number of constituents as listed below:
FLOW CFS
2 - number of nodes as listed below:
36
24
Node Year Mon Day Hr Min Sec FLOW
36 2002 01 01 00 00 00 0.000000
24 2002 01 01 00 00 00 0.000000
36 2002 01 01 01 00 00 1000.
24 2002 01 01 01 00 00 1000.
36 2002 01 02 01 00 00 1000.
24 2002 01 02 01 00 00 1000.
This file loads two manholes with a ramped inflow up to 1000 cfs to again drown out the wet wells and cause the pumps to have a steady flow.
Step 3. Use the Tab File command and use the created External Inflows File
Step 4. Run the simulation and see if the pump flows are constant.
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Steady State Flow Analysis in InfoSWMM using a Ramp DWF - Method 1
Subject: Steady State Flow Analysis in InfoSWMM using a Ramp DWF
Subject: Steady State Flow An
This can be easily created using a few steps in InfoSWMM.
Step 1: Using Scenario Explorer make a cloned Child Scenario and a cloned DWF Set which will be later modified.
Step 2: Using DB Manager and the BlockEdit tool and increase the mean DWF by a factor of 10, 100 or 1000 to drown out all Wet Wells and cause the pumps to turn on and stay turned on during the simulation in the newly created DWF Set.
Step 3. Run the batch manager and create two output files – Normal and Steady State for comparison.
Step 4. You can now compare the two scenario's using Output Manager and the Compare Graph tool. The Ramped Model should have constant flows in both links and pumps. It was not necessary to change any of the patterns.
Step 5. The model is still in balance – the excess DWF Inflow ends up as flooded flow and is listed as Internal Outflow.
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SWMM 5 Fixed Surface Water Depth Boundary Condition
A large difference between SWMM 5 and SWMM 4 is how the Groundwater Aquifer interacts with the drainage network. In SWMM 4 since the hydrology was simulated in the Runoff Block, the results saved to an interface file and the hydraulics were simulated in the Extran Block it was not possible to have a time step to time step interaction between the Aquifer and the Open Channels. SWMM 5 has integrated hydrology and hydraulics so it is possible to use either a Fixed Surface Water Depth for each Subcatchment or the Receiving Nodes Node Depth Invert Elevation – the Aquifer Bottom Elevation. The groundwater thus flows either to a fixed boundary condition as in SWMM 4 or to a time varying boundary condition.
SWMM 5 Threshold Groundwater Elevation
A large difference between SWMM 5 and SWMM 4 is how the Groundwater Aquifer interacts with the drainage network. In SWMM 4 since the hydrology was simulated in the Runoff Block, the results saved to an interface file and the hydraulics were simulated in the Extran Block it was not possible to have a time step to time step interaction between the Aquifer and the Open Channels. SWMM 5 has integrated hydrology and hydraulics so it is possible to use either a fixed Threshold Groundwater Elevation for each Subcatchment or the Receiving Nodes Invert Elevation.
Aquifers in SWMM 5
Subject: Aquifers in SWMM 5
Groundwater in SWMM 5 is model
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3 Types of Manholes in SWMM 5 and InfoSWMM
Subject: 3 Types of Manholes in SWMM 5 and InfoSWMM
There are three types of interior manholes in SWMM 5 and InfoSWMM as regards water surface elevations above the Node Rim Elevation:
1st Excess Water leaves the Node as flooded water if the water surface elevation equals the Rim Elevation (Figure 1 and Gravity Mains),
2nd Excess Water is stored in the manhole as pressurized depth if the Node Surcharge Depth is used (Figure 2 and Force Mains)
3rd Excess Water is stored above the Node Rim Elevation (Surface Ponding and Figure 3)
Figure 1. The default node in SWMM 5 and InfoSWMM has just the Manhole Invert Elevation, the program calculated elevation of the highest connected link and the Node Maximum Depth or Rim Elevation. If the Water Surface Elevation exceeds the Rim Elevation then any excess flow is lost as flooded flow.
Figure 2. A force main or pressure in SWMM 5 and InfoSWMM has the Manhole Invert Elevation, the program calculated elevation of the highest connected link, the Node Maximum Depth or Rim Elevation and the Node Surcharge Depth. If the Water Surface Elevation exceeds the Surcharge Elevation then any excess flow is lost as flooded flow but this allows more the links to have more pressure and hence more flow.
Figure 3. The flooded Node option in SWMM 5 and InfoSWMM has just the Manhole Invert Elevation, the program calculated elevation of the highest connected link, the Node Maximum Depth or Rim Elevation and Node Ponding. If the Water Surface Elevation exceeds the Rim Elevation then any excess flow is NOT lost but stored in the ponded area. The depth of the ponded area is a function of the ponding area and the excess inflow. If the water surface elevation goes below the Rim Elevation then the ponded volume flows back into the network.
InfoSWMM and Arc GIS Layer Properties for Force Mains and Gravity Mains
An important advantage of using InfoSWMM is the ability to use all of the Arc GIS layer and programming tools. For example, you can use the layer properties in the Table of Contents to color and create symbols for the force mains and gravity mains in InfoSWMM. The Force Main variable (which is a Yes/No parameter) is selected as the field value in the Symbology Tab of Layer Properties which allows you to color and size the link based on the Force Main property of is you do a Layer Join the link property and simulation results.
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InfoSWMM Note About Pump Wet Wells
Subject: Wet Well Maximum depths and Pump Start and Pump Off Depths
The Wet Well has
· An invert elevation and
· A Maximum Depth
The Pumps have
· Pump On Depth
· Pump Off Depth
· Pump Head – Discharge Curve or
· RTC Rules
The Links have a
· Invert Elevation into the Wet Well and
· Invert Elevation into the Downstream Force Main
· Crown Elevation
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| Figure 1. Wet Well Maximum Depth |
InfoSWMM or SWMM 5 Basic Runoff and Other Wet Weather Processes
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| Figure 1: Possible Sources of Input flow and Output Losses or Outflow |
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| Figure 2: Variables and Pathways on a Subcatchment Surface |
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| Figure 3: Subcatchment Pathways for Rainfall in SWMM 5 |
Detention Pond Infiltration and Evaporation Losses
Subject: Detention Pond Infiltration and Evaporation Losses
You can also add a storage pond infiltration and surface evaporation losses to the pond. The surface evaporation is added to the infiltration (computed from the green ampt parameters); a storage volume summary listing the average and maximum volume and the percent loss from the combined infiltration and evaporation from the ponds. The pond infiltration loss during a time step is basd on the areal weighed average depth, the Green Ampt infiltration and the Area of the pond.
infiltration_detetention_pond.inp Download this file
You can also add a storage pond infiltration and surface evaporation losses to the pond. The surface evaporation is added to the infiltration (computed from the green ampt parameters); a storage volume summary listing the average and maximum volume and the percent loss from the combined infiltration and evaporation from the ponds. The pond infiltration loss during a time step is basd on the areal weighed average depth, the Green Ampt infiltration and the Area of the pond.
infiltration_detetention_pond.inp Download this file
Subject: Detention Pond Infil
You can also add a storage pond infiltration and surface evaporation losses to the pond. The surface evaporation is added to theinfiltration (computed from the green ampt parameters); a storage volume summary listing the average and maximum volume and the percent loss from the combined infiltration and evap
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Detention Basin Basics in SWMM 5
Subject: Detention Basin Basics in SWMM 5
What are the basic elements of a detention pond in SWMM 5? They are common in our backyards and cities and just require a few basic elements to model. Here is a model in SWMM 5.0.022 that even has a fountain in the real pond – which we not model for now. The components of the model are:
1. An inlet to the pond with a simple time series – a subcatchment can be added to it in a more complicated model but for now we will just have a triangular time series,
2. A pipe to simulate the flow into the pond from the inlet,
3. A Storage Node to simulate the Pond that consists of a tabular area curve to estimate the depth and area relationship,
4. A Storage Node to simulate the Outlet Box of the Pond
5. Two Small Rectangular Orifices to simulate the low flow outflow from the pond at an elevation less than the weir
6. A large rectangular orifice to simulate the normal inflow to the Box
7. A rectangular weir to simulate the flow into the box when the pond water surface elevation is above the box
8. The outlet of the Box is a circular link with a Free outfall as the downstream boundary condition
9. The flow graph in the image shows the flow into the box starts from the two small orifices, next from the large orifice and finally from the top of the box or the weir.
What are the basic elements of a detention pond in SWMM 5? They are common in our backyards and cities and just require a few basic elements to model. Here is a model in SWMM 5.0.022 that even has a fountain in the real pond – which we not model for now. The components of the model are:
1. An inlet to the pond with a simple time series – a subcatchment can be added to it in a more complicated model but for now we will just have a triangular time series,
2. A pipe to simulate the flow into the pond from the inlet,
3. A Storage Node to simulate the Pond that consists of a tabular area curve to estimate the depth and area relationship,
4. A Storage Node to simulate the Outlet Box of the Pond
5. Two Small Rectangular Orifices to simulate the low flow outflow from the pond at an elevation less than the weir
6. A large rectangular orifice to simulate the normal inflow to the Box
7. A rectangular weir to simulate the flow into the box when the pond water surface elevation is above the box
8. The outlet of the Box is a circular link with a Free outfall as the downstream boundary condition
9. The flow graph in the image shows the flow into the box starts from the two small orifices, next from the large orifice and finally from the top of the box or the weir.
InfoSewer Link and Head Calculations for Steady Flow
Note: Steady State InfoSewer solution solves for the link flow and node heads
Here is an example of how the Steady State InfoSewer solution solves for the link flow and node heads or depths:
Here is one example of this sequence of events: The downstream head at the outfall causes a backwater condition in all of the links. The d/D and q/Q is based on the manhole loading flow in the 1st pass and indicates the pipe is NOT full. However, in the 2nd Pass where the manhole depths are calculated from downstream to upstream the effect of the downstream boundary condition is felt. The head shows that there is a full downstream boundary condition which is reflected in the condition of backwater and in the adjusted depth value. The links are now full and the full depth is reflected in the value of the adjusted depth and the graphical presentation.
How to interpret this result:
1. Based on the manhole loading to the network the pipes are NOT full which is indicated by the value of d/D and q/Q, however
2. Based on the head calculations which account for downstream boundary conditions the pipes are full due to the backwater effect. The backwater condition is reflected in the value of the adjusted depth – the adjusted depth shows the pipe to be full.
Figure 1. Backwater is caused by the downstream boundary condition and shows full pipes but d/D is less than 1 based on the 1st Pass Link Flow Values.
Figure 2. InfoSewer solves for the flows in the links in the 1st pass and the heads at the nodes in the 2nd pass for the Steady State solution.
Figure 3. Pipe Summary Table Shows the Pipe Adjustments based on 2nd Pass Head calculations and the d/D and q/Q values from the 1st Pass Link Flow Calculations.
Figure 4: Two Pass Solution for InfoSewer (1) Flow and (2) Head
Here is an example of how the Steady State InfoSewer solution solves for the link flow and node heads or depths:
• 1ST Flow is computed in each link and d and d/D is calculated based on pipe flow and manhole loading data and not the adjusted data from the 2nd pass.
• 2nd InfoSewer adjusts the link depth based on the manhole head and lists the adjusted depth in the browser and the Report Table after the manhole depths are calculated from downstream to upstream in the network.
• Result: The HGL graph shows the link d and d/D based on pipe flow not the adjusted depth so you are looking at the results of the 1st pass in the links and the 2nd Pass in the Nodes in a HGL Plot for a Steady State Simulation.
How to interpret this result:
1. Based on the manhole loading to the network the pipes are NOT full which is indicated by the value of d/D and q/Q, however
2. Based on the head calculations which account for downstream boundary conditions the pipes are full due to the backwater effect. The backwater condition is reflected in the value of the adjusted depth – the adjusted depth shows the pipe to be full.
Figure 1. Backwater is caused by the downstream boundary condition and shows full pipes but d/D is less than 1 based on the 1st Pass Link Flow Values.
Figure 2. InfoSewer solves for the flows in the links in the 1st pass and the heads at the nodes in the 2nd pass for the Steady State solution.
Figure 3. Pipe Summary Table Shows the Pipe Adjustments based on 2nd Pass Head calculations and the d/D and q/Q values from the 1st Pass Link Flow Calculations.
Figure 4: Two Pass Solution for InfoSewer (1) Flow and (2) Head
Note: State InfoSewer solution solves for the link flow and node heads
Here is an example of how the Steady State InfoSewer
• 1ST Flow is computed in each link and d and d/D is calculated based on pipe flow and manhole loading data and not the adjusted data from the 2nd pass.
• 2nd InfoSewer
• Result: The HGL graph shows the link d and d/D based on pipe flow not the adjusted depth so you are looking at the results of the 1st pass in the links and the 2nd Pass in the Nodes in a HGL Plot for a Steady State Simulation.
Here is one example of this sequence of events: The downstream head at the outfall causes a backwater condition in all of the links. The d/D and q/Q is based on the manhole loading flow in the 1st pass and indicates the pipe is NOT full. However, in the 2nd Pass where the manhole depths are calculated from downstream to upstream the effect of the downstream boundary condition is felt. The head shows that there is a full downstream boundary condition which is reflected in the condition of backwater and in the adjusted depth value. The links are now full and the full depth is reflected in the value of the adjusted depth and the graphical presentation.
How to interpret this result:
1. Based on the manhole loading to the network the pipes are NOT full which is indicated by the value of d/D and q/Q, however
2. Based on the head calculations which account for downstream boundary conditions the pipes are full due to the backwater effect. The backwater condition is reflected in the value of the adjusted depth – the adjusted depth shows the pipe to be full.
Figure 1. Backwater is caused by the downstream boundary condition and shows full pipes but d/D is less than 1 based on the 1st Pass Link Flow Values.
Figure 2. InfoSewer solves for the flows in the links in the 1st pass and the heads at the nodes in the 2nd pass for the Steady State solution.
Figure 3. Pipe Summary Table Shows the Pipe Adjustments based on 2nd Pass Head calculations and the d/D and q/Q values from the 1st Pass Link Flow Calculation
Figure 4: Two Pass Solution for InfoSewer (1) Flow and (2) Head
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