Summary: Permeable pavement modeling exercises, modeling exercise other LID systems
Name: _____________________
Date: _____________________
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
General instructions: You may model facility dimensions to the nearest half foot.
Site:
WSU Extension in Everett
2000 Tower St. Everett, WA 98201
Site Design Assumptions:
Predominant Soil:
Till
Pre-developed Land Cover:
Forest
Site:
Post-developed Land Cover:
Impervious
Design Standard:
Water Quality Treatment (91% Infiltration)
Project:
New construction of 5,000 square foot moderately sloped parking lot. Design a
bioretention system to provide water quality treatment for all 5,000 sf of
parking area.
Facility Design Assumptions:
Sideslopes:
3:1
Ponding Depth:
6 inches
Freeboard:
6 inches
BSM Thickness:
18 inches
BSM Porosity:
40 % effective porosity (“porosity†– “wiltingâ€)
(46 % porosity in WWHM)
BSM Infiltration Rate:
6 inches/hour
Native Soil Infiltration Rate:
0.5 inches/hour
Overflow pipe diameter:
12 inches
Assume:
No underdrain permitted
Square facility geometry
Neglect facility footprint in post-developed area
15 minute computational timestep
Results:
WWHM
Facility Bottom Area:
___________ square feet
Facility Footprint:
___________ square feet
Percent of Development:
___________ (top area)
MGSFlood
Facility Bottom Area:
___________ square feet
Facility Footprint:
___________ square feet
Percent of Development:
___________ (top area)
Exercise #1: Modeling Bioretention and Permeable Pavement
Exercise #1a: Bioretention (Water Quality)
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
Impervious
Design Standard:
Flow Control (match predeveloped flows and
durations from 50% 2-year to full 50-year
recurrence interval flow)
Project:
New construction of 5,000 square foot moderately sloped parking lot. Design a
bioretention system to provide flow control for all 5,000 sf of parking area. Use
same facility assumptions as Exercise 1a.
Use a 15 minute computational timestep.
Results:
MGSFlood
Facility Bottom Area:
___________ square feet
Facility Footprint:
___________ square feet
Percent of Development:
___________%
Exercise #1b: Bioretention (Flow Control)
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
Impervious/Permeable Pavement
Design Standard:
Flow Control (match predeveloped flows and
durations from 50% 2-year to full 50-year
recurrence interval flow)
Project:
New construction of 5,000 square foot parking lot. Design a moderately sloped
permeable pavement facility to provide flow control for 2,000 square feet of
permeable pavement (parking stalls) and run-on from 3,000 square feet of
adjacent impervious parking area (driving lanes).
Facility Design Assumptions:
Pavement Area:
2,000 square feet
Pavement Slope:
2 % (model as flat without check dams – assume
design will incorporate check dams to provide
required average ponding depth)
Pavement Infiltration Rate:
50 inches/hour
Gravel Porosity:
30%
Native Soil Infiltration Rate:
0.5 inches/hour
Use a 15 minute computational timestep.
Results:
WWHM
Average Ponding Depth:
___________ feet
MGSFlood
Average Ponding Depth:
___________ feet
Exercise #1c: Permeable Pavement
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
WSU Extension in Everett
2000 Tower St. Everett, WA 98201
Site Design Assumptions:
Predominant Soil:
Till
Pre-developed Land Cover:
Forest
Site:
Post-developed Land Cover:
Green Roof
Design Standard:
Project:
New construction of 5,000 square foot green roof. Evaluate performance of
Green Roof in MGS Flood and WWHM. Determine how WWHM Green Roof
parameters impact 2-year and 25-year flows from the baseline configuration.
Use a 15-minute computational timestep.
Baseline Green Roof Design Assumptions:
Green Area
0.115 acres
Depth of Material
4 inch
Slope of Rooftop
0.001 (ft/ft)
Vegetative Cover
Ground Cover
Length of Rooftop
50 ft
Results:
MGS Flood Recurrence Interval Flows
2-year:
___________ cfs
25-year:
___________ cfs
WWHM Recurrence Interval Flows
2-year:
___________ cfs
25-year:
___________ cfs
WWHM Green Roof Parameter
2-year
(cfs)
25-year
(cfs)
Δ from Baseline Green Roof
in WWHM
Vegetative Cover
Shrubs
Slope of Roof
0.02 ft/ft
Depth of Material
8 inch
Length of Rooftop
100 ft
Exercise #2a: Green Roof
Exercise #2: Modeling Green Roofs and Dispersion
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
Green Roof
Design Standard:
Flow Control
Project:
New construction of 5,000 square foot green roof. Design a bioretention system
downstream of the green roof to provide flow control for the site.
Bioretention Design Assumptions:
Sideslopes:
3:1
Ponding Depth:
6 inches
Freeboard:
6 inches
BSM Thickness:
18 inches
BSM Porosity:
40 %
BSM Infiltration Rate:
6 inches/hour
Native Soil Infiltration Rate:
0.5 inches/hour
Overflow Diameter:
12 inch
Assume:
No underdrain permitted
Square facility geometry
Neglect facility footprint in post-developed area
15 minute computational timestep
Results:
MGSFlood
Facility Bottom Area:
___________ square feet
How does this facility compare to the facility sized in exercise 1b?
Smaller / Larger By how much? ___________%
Exercise #2b: Green Roof to Bioretention
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
Impervious
Design Standard:
Project:
New construction of 5,000 square foot moderately sloped parking area.
Determine the performance of sheet flow dispersion in the adjacent lawn area
(5,000 square feet) next to the parking lot.
Dispersion Design Assumptions:
Option 1: Model parking lot as lateral flow impervious basin routed to a
lateral flow soil basin (only available in WWHM).
Option 2: Model impervious area as grass.
Results:
Option 1
Option 2
WWHM
Unmanaged Surface(s)
2-year:
___________ cfs
2-year:
___________ cfs
25-year:
___________ cfs
25-year:
___________ cfs
Dispersed Surface
2-year:
___________ cfs
2-year:
___________ cfs
25-year:
___________ cfs
25-year:
___________ cfs
Reduction in Recurrence Interval Flows (from unmanaged):
2-year:
___________%
2-year:
___________%
25-year:
___________%
25-year:
___________%
MGSFlood Recurrence Interval Flow
Unmanaged Surface(s)
2-year:
___________ cfs
25-year:
___________ cfs
Dispersed Surface
2-year:
___________ cfs
25-year:
___________ cfs
Reduction in Recurrence Interval Flows (from unmanaged):
2-year:
___________%
25-year:
___________%
Which technique (green roof or dispersion) better manages low flows (2-year)?
______________________________________________________________________
Which technique (green roof or dispersion) better manages high flows (25-year)?
______________________________________________________________________
Why? _________________________________________________________________
Exercise #2c: Dispersion
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Hawks Prairie Gold Course
8383 Vicwood Lane Lacey, WA 98516
Site Design Assumptions:
Predominant Soil:
Till
Pre-developed Land Cover:
Forest
Site:
Post-developed Land Cover:
See Development Plan (attached).
Design Standard:
Flow Control
Project:
New construction of single residential lot. Design a bioretention system at the
downstream end of the property to provide flow control for the lot.
Facility Design Assumptions:
Sideslopes:
3:1
Ponding Depth:
6 inches
Freeboard:
6 inches
BSM Thickness:
18 inches
BSM Porosity:
40 %
BSM Infiltration Rate:
6 inches/hour
Native Soil Infiltration Rate:
0.5 inches/hour
Overflow Structure Diameter:
12 inches
Assume:
No underdrain permitted
Square facility geometry
Subtract bioretention bottom area from lawn area
5 minute computational timestep
Results:
MGSFlood
Facility Bottom Area:
___________ square feet
Exercise #3: Modeling a Residential Development
Exercise #3a:
Driveway and
Walkway
Roof
Parcel
Bioretention
(BMP T7.30) (MR7)
Lawn on Till
_____ sf
____ sf
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
See Development Plan (attached).
Design Standard:
Project:
Determine performance of List #2 BMPs (see Figure 2) for a single lot. Assume
roof area managed by bioretention facility, at-grade impervious managed by
permeable pavement, and lawn area flows to the POC unmanaged.
Bioretention Design Assumptions:
Bioretention Facility Sizing Factor: 5%
Sideslopes:
3:1
Ponding Depth:
6 inches
Freeboard:
6 inches
BSM Thickness:
18 inches
BSM Porosity:
40 %
BSM Infiltration Rate:
6 inches/hour
Native Soil Infiltration Rate:
0.5 inches/hour
Overflow Structure Diameter:
12 inches
Assume:
No underdrain permitted
Square facility geometry
Subtract bioretention bottom area from lawn area
5 minute computational timestep
Permeable Pavement Design Assumptions:
Pavement Slope (ft/ft)
0.05
Trench Slope (ft/ft)
0.0
Pavement Infiltration Rate (in/hr)
Native Infiltration (in/hr)
0.5
Gravel Porosity (%)
Trench Depth (ft)
0.25
Soil Quality and Depth Assumptions: Modeled as Pasture on Till
Results:
Bioretention Bottom Area:
___________ square feet
Lawn Area (less bio bottom area):
___________ square feet
2-year peak flow: ___________ cfs
LID Standard: Pass / Fail
25-year peak flow: ___________ cfs
Flow Control Standard: Pass / Fail
Exercise #3b:
Driveway and
Walkway
Roof
Parcel
Bioretention
(BMP T7.30) (MR5)
Permeable
Pavement
(BMP T5.15)
(Concrete)
Lawn
Soil Quality and Depth
(BMP T5.13)
_____ sf
____ sf
_____ sf
POC
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
See Development Plan (attached).
Design Standard:
Project:
Determine performance of List #2 BMPs (see Figure 3) for the right-of-way
adjacent to two lots.
Right-of-Way Design Assumptions:
Lot Width (ft)
Number of Lots
Right-of-way Width (ft)
Roadway Width (ft)
Sidewalk Width (ft)
10 (5 ft both sides of road)
Planter Strip Width (ft)
Permeable Pavement Roadway and Sidewalk Design Assumptions:
Pavement Slope (ft/ft)
0.01
Trench Slope (ft/ft)
0.0
Pavement Infiltration Rate (in/hr)
Native Infiltration (in/hr)
0.5
Gravel Porosity (%)
Trench Depth (ft)
0.25
Soil Quality and Depth Assumptions:
Modeled as Pasture on Till (for planter strip area)
Results:
MGSFlood
2-year peak flow: ___________ cfs LID Standard: Pass / Fail
25-year peak flow: ___________ cfs
Flow Control Standard: Pass / Fail
Exercise #3c:
POC
Sidewalk
Roadway
Lawn
Soil Quality and
Depth (BMP
T5.13)
Permeable
Pavement
(BMP T5.15)
(Concrete)
Right-of-Way
Permeable
Pavement (BMP
T5.15) (Asphalt)
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
See Development Plan (attached).
Design Standard:
Project:
Size a regional detention pond to meet the flow control standard for two lots
and the right-of-way assuming the facilities used in Exercise 3b and 3c.
Regional Detention Pond Design Assumptions:
Sideslopes
3:1
Ponding Depth
2 feet
Freeboard
12 inches
Infiltration
none
Assume:
Single orifice configuration (0.5 inch min. diameter)
Area Name
Area (sf)
Area (acres)
Modeled Land Cover/BMP
Lot 1
Driveway
Roof
Lawn
Walkway
Bioretention
Lot 2
Driveway
Roof
Lawn
Walkway
Bioretention
Right-of-Way
Roadway
Lawn
Sidewalk
Total Area
Results:
MGSFlood
Facility Bottom Area:
___________ square feet
Exercise #3d:
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
POC
Sidewalk
Roadway
Lawn
Soil Quality and
Depth (BMP
Permeable
Pavement
(BMP T5.15)
(Concrete)
Right-of-Way
Centralized
Facility
Combined Detention
and Wetpool
(BMP T10.40)
Driveway and
Walkway
Roof
Parcel
Bioretention
(BMP T7.30) (MR5)
Permeable
Pavement
(BMP T5.15)
(Concrete)
Permeable
Pavement (BMP
T5.15) (Asphalt)
(Basic)
Lawn
Soil Quality and
Depth (BMP T5.13)
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Site: WSU Extension
600 128th Street SE
Everett, WA
Instructions: Review example hydrologic modeling memo and attached WWHM model output
report. Identify discrepancies between the memo and the output report and errors
in model inputs and/or calculations.
Results:
Description of Error/Discrepancy
Location of Error/Discrepancy
Exercise #4:
Date: _____________________
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
General instructions: You may model facility dimensions to the nearest half foot.
Site:
WSU Extension in Everett
2000 Tower St. Everett, WA 98201
Site Design Assumptions:
Predominant Soil:
Till
Pre-developed Land Cover:
Forest
Site:
Post-developed Land Cover:
Impervious
Design Standard:
Water Quality Treatment (91% Infiltration)
Project:
New construction of 5,000 square foot moderately sloped parking lot. Design a
bioretention system to provide water quality treatment for all 5,000 sf of
parking area.
Facility Design Assumptions:
Sideslopes:
3:1
Ponding Depth:
6 inches
Freeboard:
6 inches
BSM Thickness:
18 inches
BSM Porosity:
40 % effective porosity (“porosity†– “wiltingâ€)
(46 % porosity in WWHM)
BSM Infiltration Rate:
6 inches/hour
Native Soil Infiltration Rate:
0.5 inches/hour
Overflow pipe diameter:
12 inches
Assume:
No underdrain permitted
Square facility geometry
Neglect facility footprint in post-developed area
15 minute computational timestep
Results:
WWHM
Facility Bottom Area:
___________ square feet
Facility Footprint:
___________ square feet
Percent of Development:
___________ (top area)
MGSFlood
Facility Bottom Area:
___________ square feet
Facility Footprint:
___________ square feet
Percent of Development:
___________ (top area)
Exercise #1: Modeling Bioretention and Permeable Pavement
Exercise #1a: Bioretention (Water Quality)
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
Impervious
Design Standard:
Flow Control (match predeveloped flows and
durations from 50% 2-year to full 50-year
recurrence interval flow)
Project:
New construction of 5,000 square foot moderately sloped parking lot. Design a
bioretention system to provide flow control for all 5,000 sf of parking area. Use
same facility assumptions as Exercise 1a.
Use a 15 minute computational timestep.
Results:
MGSFlood
Facility Bottom Area:
___________ square feet
Facility Footprint:
___________ square feet
Percent of Development:
___________%
Exercise #1b: Bioretention (Flow Control)
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
Impervious/Permeable Pavement
Design Standard:
Flow Control (match predeveloped flows and
durations from 50% 2-year to full 50-year
recurrence interval flow)
Project:
New construction of 5,000 square foot parking lot. Design a moderately sloped
permeable pavement facility to provide flow control for 2,000 square feet of
permeable pavement (parking stalls) and run-on from 3,000 square feet of
adjacent impervious parking area (driving lanes).
Facility Design Assumptions:
Pavement Area:
2,000 square feet
Pavement Slope:
2 % (model as flat without check dams – assume
design will incorporate check dams to provide
required average ponding depth)
Pavement Infiltration Rate:
50 inches/hour
Gravel Porosity:
30%
Native Soil Infiltration Rate:
0.5 inches/hour
Use a 15 minute computational timestep.
Results:
WWHM
Average Ponding Depth:
___________ feet
MGSFlood
Average Ponding Depth:
___________ feet
Exercise #1c: Permeable Pavement
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
WSU Extension in Everett
2000 Tower St. Everett, WA 98201
Site Design Assumptions:
Predominant Soil:
Till
Pre-developed Land Cover:
Forest
Site:
Post-developed Land Cover:
Green Roof
Design Standard:
Project:
New construction of 5,000 square foot green roof. Evaluate performance of
Green Roof in MGS Flood and WWHM. Determine how WWHM Green Roof
parameters impact 2-year and 25-year flows from the baseline configuration.
Use a 15-minute computational timestep.
Baseline Green Roof Design Assumptions:
Green Area
0.115 acres
Depth of Material
4 inch
Slope of Rooftop
0.001 (ft/ft)
Vegetative Cover
Ground Cover
Length of Rooftop
50 ft
Results:
MGS Flood Recurrence Interval Flows
2-year:
___________ cfs
25-year:
___________ cfs
WWHM Recurrence Interval Flows
2-year:
___________ cfs
25-year:
___________ cfs
WWHM Green Roof Parameter
2-year
(cfs)
25-year
(cfs)
Δ from Baseline Green Roof
in WWHM
Vegetative Cover
Shrubs
Slope of Roof
0.02 ft/ft
Depth of Material
8 inch
Length of Rooftop
100 ft
Exercise #2a: Green Roof
Exercise #2: Modeling Green Roofs and Dispersion
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
Green Roof
Design Standard:
Flow Control
Project:
New construction of 5,000 square foot green roof. Design a bioretention system
downstream of the green roof to provide flow control for the site.
Bioretention Design Assumptions:
Sideslopes:
3:1
Ponding Depth:
6 inches
Freeboard:
6 inches
BSM Thickness:
18 inches
BSM Porosity:
40 %
BSM Infiltration Rate:
6 inches/hour
Native Soil Infiltration Rate:
0.5 inches/hour
Overflow Diameter:
12 inch
Assume:
No underdrain permitted
Square facility geometry
Neglect facility footprint in post-developed area
15 minute computational timestep
Results:
MGSFlood
Facility Bottom Area:
___________ square feet
How does this facility compare to the facility sized in exercise 1b?
Smaller / Larger By how much? ___________%
Exercise #2b: Green Roof to Bioretention
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
Impervious
Design Standard:
Project:
New construction of 5,000 square foot moderately sloped parking area.
Determine the performance of sheet flow dispersion in the adjacent lawn area
(5,000 square feet) next to the parking lot.
Dispersion Design Assumptions:
Option 1: Model parking lot as lateral flow impervious basin routed to a
lateral flow soil basin (only available in WWHM).
Option 2: Model impervious area as grass.
Results:
Option 1
Option 2
WWHM
Unmanaged Surface(s)
2-year:
___________ cfs
2-year:
___________ cfs
25-year:
___________ cfs
25-year:
___________ cfs
Dispersed Surface
2-year:
___________ cfs
2-year:
___________ cfs
25-year:
___________ cfs
25-year:
___________ cfs
Reduction in Recurrence Interval Flows (from unmanaged):
2-year:
___________%
2-year:
___________%
25-year:
___________%
25-year:
___________%
MGSFlood Recurrence Interval Flow
Unmanaged Surface(s)
2-year:
___________ cfs
25-year:
___________ cfs
Dispersed Surface
2-year:
___________ cfs
25-year:
___________ cfs
Reduction in Recurrence Interval Flows (from unmanaged):
2-year:
___________%
25-year:
___________%
Which technique (green roof or dispersion) better manages low flows (2-year)?
______________________________________________________________________
Which technique (green roof or dispersion) better manages high flows (25-year)?
______________________________________________________________________
Why? _________________________________________________________________
Exercise #2c: Dispersion
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Hawks Prairie Gold Course
8383 Vicwood Lane Lacey, WA 98516
Site Design Assumptions:
Predominant Soil:
Till
Pre-developed Land Cover:
Forest
Site:
Post-developed Land Cover:
See Development Plan (attached).
Design Standard:
Flow Control
Project:
New construction of single residential lot. Design a bioretention system at the
downstream end of the property to provide flow control for the lot.
Facility Design Assumptions:
Sideslopes:
3:1
Ponding Depth:
6 inches
Freeboard:
6 inches
BSM Thickness:
18 inches
BSM Porosity:
40 %
BSM Infiltration Rate:
6 inches/hour
Native Soil Infiltration Rate:
0.5 inches/hour
Overflow Structure Diameter:
12 inches
Assume:
No underdrain permitted
Square facility geometry
Subtract bioretention bottom area from lawn area
5 minute computational timestep
Results:
MGSFlood
Facility Bottom Area:
___________ square feet
Exercise #3: Modeling a Residential Development
Exercise #3a:
Driveway and
Walkway
Roof
Parcel
Bioretention
(BMP T7.30) (MR7)
Lawn on Till
_____ sf
____ sf
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
See Development Plan (attached).
Design Standard:
Project:
Determine performance of List #2 BMPs (see Figure 2) for a single lot. Assume
roof area managed by bioretention facility, at-grade impervious managed by
permeable pavement, and lawn area flows to the POC unmanaged.
Bioretention Design Assumptions:
Bioretention Facility Sizing Factor: 5%
Sideslopes:
3:1
Ponding Depth:
6 inches
Freeboard:
6 inches
BSM Thickness:
18 inches
BSM Porosity:
40 %
BSM Infiltration Rate:
6 inches/hour
Native Soil Infiltration Rate:
0.5 inches/hour
Overflow Structure Diameter:
12 inches
Assume:
No underdrain permitted
Square facility geometry
Subtract bioretention bottom area from lawn area
5 minute computational timestep
Permeable Pavement Design Assumptions:
Pavement Slope (ft/ft)
0.05
Trench Slope (ft/ft)
0.0
Pavement Infiltration Rate (in/hr)
Native Infiltration (in/hr)
0.5
Gravel Porosity (%)
Trench Depth (ft)
0.25
Soil Quality and Depth Assumptions: Modeled as Pasture on Till
Results:
Bioretention Bottom Area:
___________ square feet
Lawn Area (less bio bottom area):
___________ square feet
2-year peak flow: ___________ cfs
LID Standard: Pass / Fail
25-year peak flow: ___________ cfs
Flow Control Standard: Pass / Fail
Exercise #3b:
Driveway and
Walkway
Roof
Parcel
Bioretention
(BMP T7.30) (MR5)
Permeable
Pavement
(BMP T5.15)
(Concrete)
Lawn
Soil Quality and Depth
(BMP T5.13)
_____ sf
____ sf
_____ sf
POC
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
See Development Plan (attached).
Design Standard:
Project:
Determine performance of List #2 BMPs (see Figure 3) for the right-of-way
adjacent to two lots.
Right-of-Way Design Assumptions:
Lot Width (ft)
Number of Lots
Right-of-way Width (ft)
Roadway Width (ft)
Sidewalk Width (ft)
10 (5 ft both sides of road)
Planter Strip Width (ft)
Permeable Pavement Roadway and Sidewalk Design Assumptions:
Pavement Slope (ft/ft)
0.01
Trench Slope (ft/ft)
0.0
Pavement Infiltration Rate (in/hr)
Native Infiltration (in/hr)
0.5
Gravel Porosity (%)
Trench Depth (ft)
0.25
Soil Quality and Depth Assumptions:
Modeled as Pasture on Till (for planter strip area)
Results:
MGSFlood
2-year peak flow: ___________ cfs LID Standard: Pass / Fail
25-year peak flow: ___________ cfs
Flow Control Standard: Pass / Fail
Exercise #3c:
POC
Sidewalk
Roadway
Lawn
Soil Quality and
Depth (BMP
T5.13)
Permeable
Pavement
(BMP T5.15)
(Concrete)
Right-of-Way
Permeable
Pavement (BMP
T5.15) (Asphalt)
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Post-developed Land Cover:
See Development Plan (attached).
Design Standard:
Project:
Size a regional detention pond to meet the flow control standard for two lots
and the right-of-way assuming the facilities used in Exercise 3b and 3c.
Regional Detention Pond Design Assumptions:
Sideslopes
3:1
Ponding Depth
2 feet
Freeboard
12 inches
Infiltration
none
Assume:
Single orifice configuration (0.5 inch min. diameter)
Area Name
Area (sf)
Area (acres)
Modeled Land Cover/BMP
Lot 1
Driveway
Roof
Lawn
Walkway
Bioretention
Lot 2
Driveway
Roof
Lawn
Walkway
Bioretention
Right-of-Way
Roadway
Lawn
Sidewalk
Total Area
Results:
MGSFlood
Facility Bottom Area:
___________ square feet
Exercise #3d:
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
POC
Sidewalk
Roadway
Lawn
Soil Quality and
Depth (BMP
Permeable
Pavement
(BMP T5.15)
(Concrete)
Right-of-Way
Centralized
Facility
Combined Detention
and Wetpool
(BMP T10.40)
Driveway and
Walkway
Roof
Parcel
Bioretention
(BMP T7.30) (MR5)
Permeable
Pavement
(BMP T5.15)
(Concrete)
Permeable
Pavement (BMP
T5.15) (Asphalt)
(Basic)
Lawn
Soil Quality and
Depth (BMP T5.13)
Module 5.6: Advanced Topics in LID Design: Hydrologic Modeling
Site:
Site: WSU Extension
600 128th Street SE
Everett, WA
Instructions: Review example hydrologic modeling memo and attached WWHM model output
report. Identify discrepancies between the memo and the output report and errors
in model inputs and/or calculations.
Results:
Description of Error/Discrepancy
Location of Error/Discrepancy
Exercise #4:
Filename:
Module-5.6-Worksheets.pdf
File Type:
pdf
File Size:
227 KB
Categories:
Controlling Runoff, Education and Outreach, Source Control
