United States
Environmental Protection
\r ^1 Ğ* Agency
2014 GREEN INFRASTRUCTURE TECHNICAL ASSISTANCE PROGRAM
City of Bath
Bath, ME
Willow Street Green Infrastructure Design
Reducing Combined Sewer Overflows with Green Infrastructure
January 2017
EPA 833-R-17-012
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About the Green Infrastructure Technical Assistance Program
Stormwater runoff is a major cause of water pollution in urban areas. When rain falls in undeveloped
areas, soil and plants absorb and filter the water. When rain falls on our roofs, streets, and parking lots,
however, the water cannot soak into the ground. In most urban areas, stormwater is drained through
engineered collection systems and discharged into nearby water bodies. The stormwater carries trash,
bacteria, heavy metals, and other pollutants from the urban landscape, polluting the receiving waters.
Higher flows also can cause erosion and flooding in urban streams, damaging habitat, property, and
infrastructure.
Green infrastructure uses vegetation, soils, and natural processes to manage water and create healthier
urban environments. At the scale of a city or county, green infrastructure refers to the patchwork of
natural areas that provides habitat, flood protection, cleaner air, and cleaner water. At the scale of a
neighborhood or site, green infrastructure refers to stormwater management systems that mimic
nature by soaking up and storing water. Green infrastructure can be a cost-effective approach for
improving water quality and helping communities stretch their infrastructure investments further by
providing multiple environmental, economic, and community benefits. This multi-benefit approach
creates sustainable and resilient water infrastructure that supports and revitalizes urban communities.
The U.S. Environmental Protection Agency (EPA) encourages communities to use green infrastructure to
help manage stormwater runoff, reduce sewer overflows, and improve water quality. EPA recognizes
the value of working collaboratively with communities to support broader adoption of green
infrastructure approaches. Technical assistance is a key component to accelerating the implementation
of green infrastructure across the nation and aligns with EPA's commitment to provide community
focused outreach and support in the President's Priority Agenda Enhancing the Climate Resilience of
America's Natural Resources. Creating more resilient systems will become increasingly important in the
face of climate change. As more intense weather events or dwindling water supplies stress the
performance of the nation's water infrastructure, green infrastructure offers an approach to
increase resiliency and adaptability.
For more information, visit http://www.eDa.aov/areeninfrastructure.
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Acknowledgements
Principal USEF m
Jamie Piziali, USEPA
Christopher Kloss, USEPA
Community Team
Peter Owen, City of Bath
Andrew Deci, City of Bath
Consultant Team
Jonathan Smith, Tetra Tech
Bobby Tucker, Tetra Tech
Scott Job, Tetra Tech
Kelly Meadows, Tetra Tech
Alex Porteous, Tetra Tech
This report was developed under EPA Contract No. EP-C-11-009 as part of the 2014 EPA Green
Infrastructure Technical Assistance Program.
Cover Photo: Tetra Tech, Inc.
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Contents
1 Executive Summary 1
2 Introduction 2
2.1 Water Quality Issues/Goals 2
2.2 Project Overview and Goals 3
2.3 Project Benefits 5
2.4 Local Challenges 5
3 Green Infrastructure Opportunity Analysis 6
3.1 General Observations 6
3.2 Opportunities for Conventional Infrastructure 7
3.2.1 Infiltration 7
3.2.2 Stormwater Diversion 9
3.2.3 Overview of Conventional Infrastructure 9
3.3 Opportunities for Green Infrastructure 11
3.3.1 Distributed Bioretention Planter Boxes 11
4 Design Approach 13
4.1 Overview of SWMM 13
4.2 Existing Conditions Model 13
4.2.1 Subcatchments 14
4.2.2 Drainage Infrastructure 16
4.3 Model Calibration 18
4.4 Alternative Scenarios 19
4.4.1 Conventional Infrastructure Scenarios 20
4.4.2 Green Infrastructure Scenario 21
4.5 Modeling Results 22
4.5.1 Long-term Simulation 22
5 Conceptual Design 24
5.1 Stormwater Management Calculations 25
5.2 Cost Estimates 25
6 Conclusion 26
7 References 27
Appendix A: Willow Street Greenstreet Design
Appendix B: Willow Street Greenstreet Concept Cost Estimates
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Figures
Figure 2-1. Low-lying areas experience frequent ponding of stormwater from upslope areas and
occasional sanitary sewer overflows 3
Figure 2-2. Aerial view of Bath, including the Willow Street project area 4
Figure 3-1. Constrained conditions limit options for sewer separation in the project area 6
Figure 3-2. Open space between Crescent Street and railroad (right) provides an opportunity for a
surface infiltration bed 7
Figure 3-3. Riprap infiltration basin system 8
Figure 3-4. Vegetated infiltration basin 8
Figure 3-5. Two low elevation lots on Willow Street provide an opportunity for retrofit of an
infiltration gallery 9
Figure 3-6. Conventional infrastructure solutions identified within the Willow Street catchment
area 10
Figure 3-7. Retrofit opportunity for bioretention planter box 11
Figure 3-8. Recommended bioretention planter box retrofit locations and their associated
contributing areas 12
Figure 4-1. Subcatchment delineations for the existing conditions model 16
Figure 4-2. Combined sewer network modeled in SWMM 17
Figure 4-3. Hydraulic profile from June 13, 2014 calibration event between SMH 620 and SMH 569 18
Figure 5-1. View of Willow Street (top) and an artist's rendering of the greenstreet design (bottom) 24
Tables
Table 4-1. Subcatchment inputs to SWMM model 15
Table 4-2. Observed and modeled flooded manholes 19
Table 4-3 Infiltration practice input parameters 20
Table 4-4. Bioretention planter box assumptions 21
Table 4-5. SWMM LID Control parameters for bioretention cells 21
Table 4-6. Surcharging and flooding results for calibration event 22
Table 4-7. Surcharging and flooding results for 20-year simulation 22
Table 4-8. Total number of flooding events 23
Table 4-9. Long-term annual outflow comparison 23
Table 5-1. Summary of planning level implementation costs 25
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I Executive Summary
Like many older cities along the northern Atlantic coast, the city of Bath, Maine relies on an aging
combined sewer drainage system which exhibits areas subject to combined sewer overflows (CSOs) as a
result of insufficient system capacity. Although the city has taken steps to alleviate this condition
through the implementation of separate storm drainage systems and combined sewer improvements,
some areas of the city are not suitable for these solutions due to existing infrastructure conflicts, space
limitations, and inadequate topographic relief. One such area of the city is the Willow Street catchment
area, a historical residential neighborhood dating to the 18th century and transected by a rail line.
Although the City has upgraded the sewer system downstream of this area to improve overall system
capacity, frequent nuisance flooding and CSOs continue to occur. As a result, this technical assistance
project evaluated a range of design solutions focused on stormwater management and conveyance -
including both green and conventional "gray" infrastructure practices - to mitigate the frequency and
magnitude of CSO discharges and localized flooding.
To help evaluate the cost-effectiveness of the various infrastructure design scenarios, a Stormwater
Management Model (SWMM) was developed for the Willow Street neighborhood. The design scenarios
were developed from field investigations, input from city staff, and available information for the existing
combined sewer infrastructure network (including GIS coverages and engineering plans). The primary
design scenarios evaluated with SWMM included:
1. Centralized conventional infrastructure (both a surface and subsurface infiltration basin) at two
locations in the neighborhood
2. Diversion of stormwater runoff from the combined sewer network via new storm drains
3. Distributed green infrastructure throughout the neighborhood using bioretention planter boxes
within existing parking lanes
Based on a long-term simulation, the SWMM model results indicated that no single infrastructure
scenario would eliminate CSO occurrences within the neighborhood. Although green infrastructure
solutions can provide notable reductions in stormwater volume and CSO events within the Willow Street
subcatchment, a combination of practices incorporating both green and conventional infrastructure are
ultimately needed to reduce overflows to an acceptable frequency of occurrences. This project
demonstrated how hybrid green-gray approaches to stormwater management can solve extreme
flooding issues while providing a variety of ancillary benefits associated with green infrastructure.
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2 Introduction
Bath, Maine is located near the central coast of Maine on the Kennebec River, approximately 12 miles
north of where the river empties into the Atlantic Ocean. The city's culture has centered around
maritime activity for hundreds of years, as it is known as the "City of Ships" and is home to one of the
best known shipyards in the world (City of Bath 2014). Bath is currently home to approximately 8,500
residents (US Census 2010).
The City of Bath (City) has periodic problems with stormwater, specifically localized flooding and
combined sewer overflows (CSO) from its municipal sewer system. The City hopes to alleviate the
ongoing problems of flooding and CSOs by controlling the volume of stormwater flows with green
infrastructure. Specifically, the City will develop a plan to incorporate water storage and treatment
features, such as rain gardens, throughout the community. In addition to accomplishing these water
quality goals, the City also hopes to improve the quality of life in the adjoining neighborhoods by adding
natural, vegetative features and encouraging a garden-like appearance.
'ater Quality Issues/Goals
The Kennebec River is listed as impaired for fecal coliform from CSOs and the Maine Department of
Environmental Protection (DEP) has established a statewide total maximum daily load (TMDL) for
bacteria.
The City of Bath has been under a consent decree with DEP since 1992 to address CSO discharges. The
City has made significant progress but is struggling to eliminate the remaining four CSO outfalls. One
outfall is located in a low-lying area near Willow Street where constrained infrastructure conditions in
the upper portions of the drainage network preclude sewer separation. As a result, stormwater runoff is
managed by a combined sanitary sewer system. During larger storm events, this leads to the system
being overwhelmed, resulting in water backing up through sanitary manholes and creating flood
conditions in the neighborhood (Figure 2-1).
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E 3lp
-"i'Jf' ' Ĥ s :
Photo credit: Tetra Tech, Inc.
Figure 2-1. Low-lying areas experience frequent ponding of stormwater from upslope areas and
occasional sanitary sewer overflows
2.2 Project Overview and Goals
Like many older cities, Bath is constrained by aging or inadequate infrastructure, as well as logistical
conflicts, in attempting to identify potential solutions for issues such as CSOs. This combination of
challenges is well-represented in the selected project.
The Willow Street neighborhood is primarily comprised of a small number of residential homes and lies
adjacent to an operational railroad line and a Federally-recognized historic district. (See Figure 2-2 for an
aerial view of Bath.) City officials note that there are an unusually high number of foreclosures in this
neighborhood, adding economic distress. They also note that several homes on Willow Street have been
abandoned, likely due to the flooding issues. Unfortunately, Willow Street is a topographic low point
with no viable location for a gravity-fed discharge; the railroad line and topography limit the City's ability
to develop a separate storm sewer system. As a result, stormwater is routed into the sanitary sewer.
The City has upgraded the sewer system in the area downstream of North Street to reduce sanitary
sewer overflow issues, but the upgrades could not fully resolve the issues associated with the addition
of stormwater to the system in the headwaters of the drainage system. As a result, Willow Street
remains a troublesome location during storm events.
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Legend
Roads
Project Drainage Area
Town Boundary
em
Vicinity Map
Bath, Maine
Map produced by B. Tucker, 08-5-2014
NAD_1983_StatePlane_Maine_V_FIPS_0405
TETRA TECH
Source: Tetra Tech, Inc.
Figure 2-2. Aerial view of Bath, including the Willow Street project area
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The City envisions using green infrastructure as a way to mitigate these effects and reduce the volume
of stormwater that reaches the sanitary system, as opposed to the use of conventional "gray"
infrastructure (e.g., pipes and pump stations). City staff hope that green infrastructure can preclude the
need for what they expect would be very costly conventional infrastructure solutions.
The project involves a number of steps to identify appropriate solutions, including:
Review watershed conditions
Identify drainage characteristics, pathways, and peak flows
Develop a model of existing hydraulic conditions in the catchment
Identify green and conventional infrastructure practices and locations
The project will also document these steps, develop a conceptual design for selected practices, and
provide an estimated cost for construction.
The City also hopes to examine the potential of combining green infrastructure practices with
conventional practices. The City recognizes that the project location has an unusual number of design
constraints and it may therefore not be possible to resolve the flooding issues via green infrastructure
alone. As a result, the project will also describe several conventional infrastructure practices.
2.3 Project Benefits
As noted above, the primary benefit of the Willow Street project will be a reduction in the number and
frequency of CSO discharges and reduction of localized flooding. The City also envisions that green
infrastructure will improve groundwater recharge, as well as add natural, vegetative spaces to the
community. The project could also stabilize an economically troubled neighborhood by reducing private
property losses. Additionally, this project could serve as a model for resolving similar issues across the
New England region. City officials also anticipate incorporating the design principles into future
redevelopment efforts in the City, such as transportation projects.
ical Challenges
The project location has substantial constraints, which may limit the options for green infrastructure
practices. Certain practices may not be appropriate, or site conditions may limit the effectiveness of
otherwise appropriate practices. Although green infrastructure can reduce the frequency of flooding
and mitigate flood damage, green infrastructure practices are not solely intended to address severe
flooding, suggesting that some conventional infrastructure may also be needed. The City also needs to
develop a convincing approach in order to win over residents, the general public, and other city or local
government staff.
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3 Green Infrastructure Opportunity Analysis
On August 14, 2014, Tetra Tech met with the local community team and conducted a site visit of the
Willow Street catchment area. The purpose of the meeting and site visit was to discuss local site
conditions and identify potential opportunities for green and conventional infrastructure solutions to
address the combined sewer overflows.
3.1 General Observations
The Willow Street catchment area refers to a 45.3 acre drainage sub-basin originating near Crescent
Street and generally bounded by Washington Street to the east, High Street to the west, and North
Street to the south. The catchment area is primarily residential, served by a network of residential
streets exhibiting asphait or granite raised curbs and asphalt sidewalks typically only on one side of the
street. The catchment area is highly developed with minimal open space areas except for residential
lawns. A railroad track transects the catchment area in the north-south direction (see Figure 3-1) and
mostly parallels the main trunk of the combined sewer system in the lowest elevation portions of the
catchment area. Previous research of historical documents by City staff revealed that the railroad was
constructed after much of the catchment area was already developed and likely placed in the only
undeveloped area available at the time, along the drainage corridor. At one time there was a small
stream originating in the area most subject to frequent flooding to the north of North Street.
Photo credit: Tetra Tech, Inc.
Figure 3-1. Constrained conditions limit options for sewer separation in the project area
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3.2 Opportunities for Conventional Infrastructure
As described above, an important element of this project is to examine the capabilities of green
infrastructure as compared to conventional practices. This section of the report describes potential
conventional infrastructure practices. In Section 4 below, these practices are further analyzed using the
hydraulic model.
3.2.1 Infiltration
While available space for centralized stormwater infrastructure is limited within the project area, City
staff identified two areas within the drainage area as potential sites for conventional infrastructure.
At the first location, the design could include installing a series of linear infiltration basins in the open
space area between Crescent Avenue and the railroad track (Figure 3-2), The basins would be designed
to receive both direct runoff from Crescent Avenue, as well as diverted runoff from the catch basins
located on the south side of Crescent Avenue near York Street. The area is located within the Crescent
Street right of way and is currently vegetated with small to medium trees. It appears that the area is not
actively managed in any way. Construction of the infiltration basins would require removal of the
vegetation and minor grading to provide storage within the basins. Ground cover within the basins can
include either rip-rap/gravel, managed turf grass, or a native grass/meadow mix, as depicted by the
photo examples in Figure 3-3 and Figure 3-4.
Photo credit: Tetra Tech, Inc.
Figure 3-2. Open space between Crescent Street and railroad (right) provides an opportunity for a
surface infiltration bed
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Photo credit: Chesapeake Stormwater Network Photo credit: Tetra Tech, Inc.
Figure 3-3. Riprap infiltration basin system Figure 3-4. Vegetated infiltration basin
At the second location, a possible design could include installing a subsurface infiltration gallery in two
low elevation lots on the west side of Willow Street between the street and the railroad tracks (at
approximately 22 Willow Street and 24 Willow Street; see Figure 3-5). Construction of a subsurface
gallery would require acquisition of the parcels and demolition of any existing structures, but would
preserve the area for potential green space amenities such as a public park. Overflow from the
infiltration gallery would discharge to the combined sewer system.
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Photo credit: Tetra Tech, Inc.
Figure 3-5. Two low elevation lots on Willow Street provide an opportunity for retrofit of an infiltration
gallery
3.2.2 Stormwater Diversion
Previously, the City completed stormwater diversion projects for significant portions of the Willow
Street catchment area downstream of North Street. This project involved the installation of a dedicated
stormwater drainage system serving nearly all of the Willow Street drainage area downstream of North
Street. During the site visit, City staff identified two additional areas with suitable conditions for
diversion of stormwater to the new stormwater sewer system. These two areas consist of portions of
Bedford and North Streets between High Street and Lincoln Street. Implementation of the stormwater
diversion scenario would involve construction of a new stormwater drainage line under North Street
from High Street to Willow Street and a new stormwater drainage line under Bedford Street originating
at approximately 32 Bedford Street and terminating at High Street. Stormwater diversion would directly
reduce hydrologic loading to the Willow Street combined sewer system.
3.2.3 Overview of Conventional Infrastructure
Figure 3-6 shows the location of both the potential infiltration areas (in yellow) and stormwater
diversions (in blue), as well as the drainage areas associated with these designs.
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Legend
Dummer Street Ct
Storm Sewer Extension
Infiltration Basins
SSWR Lines
StormDrain
Model Subbasins
Wright Dr
Storm Sewer Diversion
Infiltration Basin Treatment
-Valiman
J Linden St
Green
Conventional Infrastructure Options
Treated Drainage Areas
Map produced by B. Tucker, 12-4-2014
NAD_1983_StatePlane_Maine_V_FIPS_0405
Photo credit: Tetra Tech, Inc.
Figure 3-6. Conventional infrastructure solutions identified within the Willow Street catchment area
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3.3 Opportunities for Green Infrastructure
This section of the report describes potential green infrastructure practices.
3.3.1 Distributed Bioretention Planter Boxes
During the site visit, potential locations for retrofit bioretention planter boxes were identified within the
project drainage area subcatchment for installation along the existing roadway curb edge. Installation of
the planter boxes, sometimes referred to as bump-outs, would encroach into the roadway, reducing
width. Feasible locations were determined by factors such as: roadway slope, proximity to existing
manholes or catch basins, and avoidance of adjacent obstacles like telephone poles and driveway
entrances (Figure 3-7).
Ĥ
Photo credit: Tetra Tech, Inc.
Figure 3-7. Retrofit opportunity for bioretention planter box
In many locations, both sides of the street were determined to be suitable for bioretention installations.
However, roadway widths in this area are not sufficiently wide to allow encroachment on both sides of
the roadway without impact to vehicular access In such cases, the side of the street exhibiting the best
characteristics for bioretention planter box implementation was selected. Twelve priority locations were
identified as suitable locations for bioretention planter boxes within the Willow Street catchment area.
These locations and their associated contributing drainage areas are provided in Figure 3-8.
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Legend
Dummer Street Ct
Bioretentiori Locations
SSWR Lines
StormDrain
Bioretention Drainage Areas
S09a 4
Wright Dr
f^i
S09bf r
i."
ĤJf Grove
t ~T I T*
r *
Tallrna^;
S13I)
ItpQ.
5/ 1 Linden St
! Green
Bioretention Drainages Areas
and Locations
Map produced by B. Tucker, 08-5-2014
N AD_1983_StatePlane_M ai ne_V_FIP S_0405
TETRA TECH
Source: Tetra Tech, Inc.
Figure 3-8. Recommended bioretention planter box retrofit locations and their associated contributing
areas
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4 Design Approach
An important tool for evaluating and optimizing green infrastructure solutions for storm flooding and
water quality challenges involves continuous hydro-simulation simulation models. Given the complexity
of the combined sewer network within the Bath project area, the project team selected the Stormwater
Management Model (SWMM; Rossman 2010) as the optimal tool for helping achieve the project goals.
w'mw of SWMM
SWMM is a dynamic precipitation-runoff simulation model designed for discrete event or continuous
representation of hydraulics, hydrology, and water quality. It is optimized and designed for storm event
flow management in urban area drainage systems. First developed in 1971, SWMM has undergone
numerous updates and enhancements. SWMM is currently maintained by USEPA and generically
referred to as SWMM 5 (distinguishing it from SWMM 4 which is still in use, though not updated). The
project used version 5.0.022 (released April 2011), which was the most current version available at the
time.
Modeling was performed using PCSWMM, a commercial product developed by Computational
Hydraulics International (http://www.chiwater.com/). PCSWMM implements the public-domain SWMM
5 computational engine, but provides an advanced user interface and tool set for building models and
analyzing simulation results.
Precipitation and other meteorological input data are used to drive the hydrologic response in the
simulation. SWMM 5 represents land areas as a series of subcatchments, with properties that define
retention and runoff of precipitation, infiltration, and (optionally) percolation to a shallow aquifer and
discharge from the aquifer. Subcatchments are connected to the drainage network, which may include
natural watercourses, open channels, culverts and storm drainage pipes, storage and treatment units,
outlets, diversions, and many other elements of an urban drainage system. Nodes and links are used in
SWMM 5 to define the connectivity and control within the drainage network.
4.2 Existi nditions Model
The existing conditions model (also referred to as a baseline model) represents current conditions within
the study area, and includes the recent Willow Street/Railroad Track sewer and storm drain
modifications as represented in the as-built drawings. Although PCSWMM is fully capable of modeling a
highly articulated drainage network (including all surface and subsurface stormwater infrastructure
within the subcatchment), a more simplified representation of the combined sewer and drainage
network was utilized in the model, particularly within the headwater subcatchments located further
from the sewer trunk main. This simplification was based on the lack of invert elevation data for the
headwater combined sewer network, the inherent uncertainty of long-term simulation modeling, and
strategy to focus modeling efforts on creating a higher-resolution simulation near the flooded areas of
interest.
Simulation of hydrology in PCSWMM is largely driven by meteorological data, including rainfall and
evapotranspiration (ET). The ability of a model to predict hydrologic response and pollutant generation,
fate, and transport is strongly influenced by the accuracy and appropriate representation of
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meteorological data. Meteorology data was developed from Phase 2 of the North American Land Data
Assimilation System (NLDAS-2).1
The meteorological data were obtained for the l/8th degree grid cell corresponding to the location of
the study area. A daily climate file was produced with minimum and maximum air temperature,
potential daily evapotranspiration, and average daily wind speed. An hourly precipitation file was also
produced. Both files spanned twenty years from July 1994 through June 2014. One adjustment was
performed on the precipitation file; to more accurately represent the calibration storm event occurring
on June 13, 2014, observed precipitation data were obtained from a monitoring station at Wiscasset
Airport (WBAN 94623) located a few miles from the study area. The precipitation data were in a raw
format with a variable time-step and numerous accumulated values, and could not be used directly for
representing long term hourly precipitation. However, it was possible to interpret the file and obtain
hourly precipitation values specifically for the June 13 event. Those values were inserted into the
twenty-year SWMM 5 precipitation input file to better represent the calibration storm event.
The key model parameters for hydrology and hydraulics include subcatchments and drainage
infrastructure (e.g., pipes, manholes, and catch basins). Each is described below.
4.2.1 S
The analysis of subcatchments within SWMM 5 utilized the following assumptions and resources:
Subcatchment area was calculated using geospatial datasets provided by the City (e.g., 2 ft
topographic contours, combined sewer/storm drainage networks), field verification, and
subcatchment delineations performed by a previous consultant.
The majority of impervious surface area in the watershed is comprised of: secondary roadways,
residential rooftops, and driveway/parking areas. Impervious area was calculated for each
subcatchment using two geospatial datasets provided by the City - a digitized building footprint
layer and roadway centerlines. Since the buildings coverage did not include extraneous
impervious areas like driveways, sidewalks, patios, outbuildings, etc., the modelers applied an
adjustment factor based on an average of actual impervious measurements from several
parcels.
Roadway/sidewalk areas were calculated by creating a 15 ft buffer on both sides of the road
centerline. Based on areal measurements, a 30 ft impervious right-of-way was observed as
typical within the subcatchment.
The Percent Routed parameter (a measure of impervious disconnection) was represented as the
percentage of impervious area that discharges to pervious area. This parameter was based on
the assumption that all impervious roadway runoff is routed directly to sewer drainage systems,
and only a fraction of on-lot impervious area is routed to pervious area. Note that the final
calibrated model, which used the 'percent routed' input value as a calibration parameter,
assumed that only 20% of the on-lot impervious area within each subcatchment drains directly
to pervious area. This is not unreasonable, since during large storm events, the infiltration
capacity of pervious land may be quickly overwhelmed, and the impervious areas becomes
effectively connected.
1 http://Idas.asfc.nasa.gov/index.DhD
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Default Manning's N values from EPA SWMM 5 User's Manual (Rossman 2010) were used for
overland flow. Impervious depression storage for all subcatchments was set to 0.05 inches, and
the pervious depression storage was set to 0.15 inches.
The Green-Ampt option was selected for surface infiltration. Parameters were set using
guidance from Rossman (2010) and James et al. (2005). Soil properties were based on area-
weighted USDA SSURGO data for each subcatchment. According to SSURGO, soils in a
subcatchment vary between a silty loam with HSG C, and fine sandy loam with HSG D. Area-
weighted values for suction head and initial moisture deficit were applied directly from SSURGO,
while Infiltration Conductivity values were adjusted by a factor of 0.06 (final calibration value)
since watershed modeling infiltration rates are much lower than those typically published for
saturated hydraulic conductivity.
Aquifer-groundwater modeling was not enabled due to the complexity of the parameterization,
which typically requires continuously monitored streamflow for a meaningful calibration. Soil
wetting and drying followed default SWMM 5 behavior.
Table 4-1 shows the final calculated (or calibrated) parameters for each subcatchment used in the
existing conditions model. The subwatershed delineation for the existing conditions model is shown in
Figure 4-1. As depicted, the model boundary condition was extended to just north of Winter Street to
account for the tailwater conditions that occur in the sewer main along the railroad tracks.
Table 4-1. Subcatchment inputs to SWMM model
SWS ID
Subcatchment (ac)
% Impervious
% Routed3
Slope (%)
Soil Conductivity (in/hr)
S01
0.30
60%
2%
0.65
0.24
S02
3.58
29%
19%
0.6
0.19
S03
3.59
37%
15%
1.98
0.20
S04
3.06
43%
14%
1.48
0.24
S05
0.88
77%
11%
1.12
0.24
S06
3.11
33%
15%
2.3
0.24
S07
0.84
4%
0%
0.71
0.24
S08
3.55
53%
12%
1.69
0.18
S09
2.57
61%
13%
1.49
0.22
S10
1.88
71%
17%
0.52
0.24
S11
3.63
46%
15%
1.27
0.23
S12
2.38
36%
15%
1.41
0.24
S13
1.10
61%
7%
0.89
0.22
S14
2.33
49%
18%
1.18
0.12
S15
1.20
61%
15%
2.25
0.13
S16
1.87
52%
16%
0.85
0.08
S17
6.05
44%
16%
0.94
0.06
S18
3.38
53%
11%
1.38
0.16
a Percent of impervious area that is directly routed to pervious area; used as the primary calibration parameter.
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Legend
Manholes
Modeled SSWR
SSWR Lines
StormDrain
Model Subbasins
Wright Dr
Grove
Tallrna^,
Linden St
Project Drainage Area
Bath, Maine
100 200
It
TETRA TECH
Source: Tetra Tech, Inc.
Figure 4-i. Subcatchment delineations for the existing conditions model
4.2.2 Drainage Infrastructure
Combined sewer and drainage infrastructure configurations were obtained from GIS layers, construction
drawings for the recent sewer separation project on Willow Street, and surveyed elevations of manhole
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inverts collected by City staff. The primary infrastructure information used in the model included
manhole invert elevations, pipe length/material/size, and the new storm sewer diversion configurations.
Figure 4-2 shows the manhole labels and combined sewer pipe that was included in the SWMM 5
model. Labels preceded by a "P" indicate new manholes installed as part of the Willow Street project
that did not replace an existing manhole.
Legend
Modeled Manholes
@ Manholes
Modeled SSWR
SSWR Lines
Ĥ StormDrain
/ i Grove
P-SMH-08
(Added to model)
P-SMH-11
_ 1 North St
Linden Sti...! .-j
Tfc
Source: Tetra Tech, Inc.
Figure 4-2. Combined sewer network modeled in SWMM
17
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4.3 Model Calibration
A detailed, long term calibration of the Bath flood model was not feasible for several reasons. Foremost,
flow monitoring data was not available from the City within the project sewer network. Second, recent
modifications to the combined sewer network along Willow Street and the adjacent railroad track trunk
line would have made any prior monitoring data inconsistent with the hydraulic response to the existing
sewer configuration. Instead, the modelers performed a qualitative calibration based on an extreme
flooding event from June 13, 2014, using observed locations where manholes were known to have
flooded. According to City staff, manhole covers were lifted at three manholes south of North Street
(MH's 592, 570, and 588), and three manholes north of North St. (P-SMH-06, P-SMH-07, and P-SMH-Q8).
This level of calibration is considered acceptable given that the primary project goal is to compare the
relative flood reduction impacts of various infrastructure options.
As previously indicated, the primary calibration parameters that were adjusted to simulate flood
occurrences at the targeted manhole locations included 'percent routed' and 'soil conductivity.' The
final parameter values used in the calibrated model are shown in Table 4-1.
Figure 4-3 shows a typical hydraulic profile from the June 13 calibration event. The profile includes the
main sewer line between MH-620 (new junction south of Pearl St.) and the boundary condition
manhole, MH-569, which was represented as the outfall in the model. Although the profile only includes
a selection of the overall modeled network, it shows the flooded area of interest used for model
calibration. The manholes in the visible profile that flooded during the calibration simulation are P-07,
588, and 570.
Existing Conditions
HGL Time: 6/13/2014 8:00:00 PM
Conduit 03 Conduit 35? Conduit 1482 Conduit j2 Conduit C8 Conduit C9 Conduit C10 Conduit C11 Conduit C12
Flow = 4.257 cfs Flow = 1.039 cfs Flow = 2.154 cfs Flow = 2.384 cfs Flow = 7.313 cfs Flow = 7.335 cfs Flow = 7.341 cfs Flow = 6.809 cfs Flow = 6.809 cfs
Figure 4-3. Hydraulic profile from June I 3, 2014 calibration event between SMH 620 and SMH 569
Table 4-2 compares the full list of manholes that simulated flooding during the calibration event to the
manholes with observed flooding (as reported by City staff). As shown, 4 of the 6 observed flooded
manholes also simulated flooding, in addition to the next manhole below 570 (569). Two headwater
18
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manholes (612 and 569), which had no reported flooding during the calibration event, also simulated
flooding in the calibration (although likely as a result of reduced resolution in the sewer network within
the headwater subcatchments).
Table 4-2. Observed and modeled flooded manholes
Manhole ID Observed Modeled
592 X
570
X
X
588
X
X
612
X
6341
X
569
X
P-06
X
P-07
X
X
P-08
X
X
The limited extent of observed data justified the narrow calibration time period, and these model results
do not provide a comprehensive evaluation of drainage system response among the variation in storm
timing/intensity/duration patterns that are exhibited across a range of events. However, the event-
based simulation was useful for calibrating the system response to the recently observed flooding
impacts and lifted manhole cover locations. For the calibration, the June 13 event was preceded by 20
days to more accurately represent antecedent moisture conditions.
4.4 Alternative Scenarios
To evaluate potential solutions for addressing flooding issues within the project area, the green and
conventional infrastructure opportunities identified in Section 3 were developed into distinct model
scenarios and simulated in SWMM 5. The intent was to evaluate the hydrologic and hydraulic impacts
for each scenario separately so that each approach could be evaluated independently. The alterative
scenarios evaluated include:2
Scenario 1A: Centralized Conventional Infrastructure
Surface infiltration basins along Crescent Avenue (treats S07 and S08).
Subsurface infiltration gallery along Willow Street (S10, Sll, S12, and S13)
Scenario IB: Modified Centralized Conventional Infrastructure Option
Same as Scenario 1A, but includes:
- A check valve between Manholes P-SMH-06 and P-SMH-08
2 Unfortunately, due to resource constraints, this report was not able to quantitatively analyze combinations of the various
scenarios. However, as stated above, it is possible that a hybrid of conventional and green infrastructure could be used at the
project site.
19
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Scenario 2: Stormwater Diversion
New storm drains would divert runoff from S16 and S18 to existing, separate storm sewer on
Middle Street
Scenario 3: Distributed Green Infrastructure
Includes 12 bioretention planter boxes installed throughout the watershed with approximately
4,300 sf of treatment area.
4.4.1 Conventional Infrastructure Scenarios
Scenario 1A (Centralized Conventional Infrastructure)
This scenario incorporates both of the centralized infiltration basins identified as opportunities during
field investigations. As a starting basis for design, water quality volumes for the 1 inch rainfall events
were calculated (using the Simple Method) for both sites and used to develop reasonable footprint and
storage depth targets.
Based on the calculated water quality volume, infiltration basins along Crescent Street with a 12 inch
ponding depth would require approximately 7,050 sf of area, which can conservatively fit into the
available open space area between the railroad and the street when accounting for side slopes and
setback requirements. In the case of the subsurface infiltration gallery at Willow Street, stormwater that
currently enters the new storm drain system at SMH 617 from subcatchments S10 through S13 would be
diverted to the infiltration gallery, which could statically store almost 230,000 gallons below the outlet
invert. Overflow from the infiltration basin would discharge back to existing manhole P-SMH-08. Practice
dimensions and SWMM input parameters are provided for these two opportunities in Table 4-3.
Table 4-3 Infiltration practice input parameters
Infiltration
Soil
Practice
Max. Surface
Storage
Weir Length
Weir
Orifice Dia.
Conductivity
Location
Area (sf)
Depth (ft)
(ft)
Height (ft)
(in)
(in/hr)
Crescent Ave.
7,980
1
12
0.12
N/A
0.12
Willow St.
10,200
3
N/A
N/A
15
0.24
Scenario IB (Modified Centralized Conventional Infrastructure Option)
This scenario involves the low-cost option of installing a check valve or flap gate in the new Willow
Street connection and was simulated to evaluate the impact on hydraulics in the flooded area of
interest. The check valve would be installed below P-SMH-08. This scenario would prevent backflow in
the main sewer trunk line from flooding the manholes east of P-SMH-6. This scenario was identified
during model simulation as an enhancement of the original scenario configuration.
Scenario 2 (Stormwater Diversion)
This is also a conventional infrastructure option that would involve installing new storm sewer to divert
runoff from subcatchments S16 and S18 to the existing storm drainage network on Middle Street. For
the SWMM 5 simulation, these two subcatchments (and their connecting sanitary sewer network) was
removed from the existing conditions (calibration) model and re-simulated.
20
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4.4.2 Green Infrastructure Scenario
Scenario 3 (Distributed Green Infrastructure)
For the purposes of conceptual modeling, all bioretention cells were assumed to have internal widths of
5 feet, ponding depths of 6 inches, and variable lengths based on site constraints. Table 4-4 shows both
the conceptual BMP area for each identified bioretention cell, as well as the percentage of water quality
volume that can be instantaneously stored from its respective subcatchment. More detailed input
parameters used to model bioretention cells within SWMM's LID Controls function are displayed in
Table 4-5. As is common with many green street retrofits, existing road/utility configurations and other
site constraints prevent roadside linear bioretention cells from being adequately sized to treat the entire
water quality volume; this design will also not provide enough capacity for significant mitigation of peak
runoff flows which may limit its potential for reducing CSO frequency.
Table 4-4. Bioretention planter box assumptions
BMP ID
Unit Length (ft) BMP Area (sf)
Subcatchment (ac)
% WQ Treated
S01
85 425
0.20
64%
S03
100 500
3.40
8%
S04
100 500
2.40
11%
S05
80 400
0.12
58%
S09a
50 250
0.56
9%
S09b
80 400
0.41
32%
S10
75 375
0.69
17%
S13a
30 150
0.08
38%
S13b
60 300
0.35
33%
S13c
80 400
0.53
21%
S16
70 350
0.24
21%
S17
45 225
0.21
15%
Table 4-5. SWMM LID Control parameters for bioretention cells
Input Parameter
Value
Surface storage (in)
6
Surface
Vegetation volume (fraction)
0.2
Surface roughness (n)
0.25
Surface slope (%)
2.2
Soil thickness (in)
18
Porosity (vol. fraction)
0.437
Field capacity (vol. fraction)
0.105
Soil
Wilting point (vol. fraction)
0.047
Conductivity (in/hr)
1.18
Conductivity slope
7
Suction head (in)
2.4
Storage depth (in)
12
Storage
Void ratio (voids/solids)
0.54
Conductivity (in/hr)
0.2
Clogging factor
0
Drain coefficient (in/hr)
5
Underdrain
Drain exponent
1
Drain offset height (in)
0
21
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4.5 Modeling Results
Table 4-6 shows a summary of the modeling results from the June 13 event simulation. The results
indicate that response of the infiltration basin scenario without backflow prevention (Scenario 1A)
significantly mitigates flooding duration and volume for the event relative to the other modelled
scenarios.
Table 4-6. Surcharging and flooding results for calibration event
Surcharge
Flooding
Model Scenario
# MH's Total Hrs.
# MH's
Total Hrs.
Total Vol. (cf)
Existing Conditions
11
29.4
6
4.7
35,830
Scenario 1A (Conventional)
11
32.7
5
2.2
1,200
Scenario 1B (Modified Conventional)
9
19.9
5
4.2
18,315
Scenario 2 (Diversion)
11
24.2
5
4.1
24,600
Scenario 3 (Green Infrastructure)
11
28.9
5
4.7
35,560
4.5.1 Long-term Simulation
To better evaluate the system's response across a range of storm events, a 20-year simulation period
(7/1/1994 - 6/30/2014) was performed for each scenario. Table 4-7 shows the overall flooding duration
and overflow volumes and Table 4-8 shows the number of individual flooding events over the 20-year
simulation period. The historic rainfall record also predicts significant flood reductions from the
centralized infiltration basin scenarios. Collectively, the two infiltration basins were sized to provide over
7000 c.f. of runoff storage. The green infrastructure scenario (Scenario 3), which only provides
approximately 2,140 c.f. of surface storage, yields little impact in reducing flood occurrences.
Table 4-7. Surcharging and flooding results for 20-year simulation
Flooding
Model Scenario
# MH's
Total Hrs.
(%)
Reduction
Hrs.
Total Vol.
(gal 10A6)
(%) Reduction
Vol.
Existing Conditions
12
263
-
11.1
-
Scenario 1A (Conventional)
12
84
68
3.5
69
Scenario 1B (Modified Conventional)
12
138
47
4.8
57
Scenario 2 (Diversion)
11
158
40
6.6
40
Scenario 3 (Green Infrastructure)
12
246
6
10.6
4
To provide a more relevant analysis with regards to regulatory reporting requirements of combined
sewer overflow occurrences, the number of discrete flooding events was calculated for two manholes.
The two selected manholes - SMH 570 and P-SMH-08 - were the most frequently flooded manholes
based on both the calibration simulation and the long-term continuous simulation. According to Table
4-8, which shows the number of discrete flooding events at these two manholes by model scenario, the
centralized infiltration basins (Scenario 1A) indicate a significant reduction in flooding frequencies.
22
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Table 4-8. Total number of flooding events
Modelled Combined Sewer Overflows
Scenario
Parameter
Total (20-yrs)
Annual Average
Existing
# events
107
5.4
% reduction
-
-
Scenario 1A
# events
38
1.9
% reduction
65%
Scenario 1B
# events
44
2.2
% reduction
59%
Scenario 2
# events
60
3.0
% reduction
44%
Scenario 3
# events
97
4.9
% reduction
9%
Green infrastructure BMPs, especially those implemented under retrofit scenarios, are not typically
optimal for peak flood control compared to centralized detention facilities. As a result, the modeling
results were also evaluated for the impacts on long-term hydrology within the subcatchment. Table 4-9
shows the total annual external outflow from the modeled sewer network, as predicted for each
scenario. As shown, the conventional infrastructure scenarios yield significantly greater annual volume
reductions as compared to the other scenarios.
Table 4-9. Long-term annual outflow comparison
Scenario Total Outflow (ac-ft) % Reduction (vol)
Existing 1136 n/a
Existing 1136 n/a
23
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5 Conceptual Design
As described in Section 4, each of the scenarios evaluated as part of the modelling analysis showed a
reduction in CSO frequency within the known problem areas. Green infrastructure can provide a marked
reduction in stormwater flows, flooding and CSO events. This section describes a conceptual design for
these measures.
To help visualize the potential green infrastructure scenario for community consideration, a conceptual
design was developed for the implementation of the twelve distributed bioretention areas throughout
the Willow Street catchment area. The conceptual design includes a rendering of a potential
bioretention installation on Bedford Street, as seen in Figure 5-1. A complete conceptual design is
provided in Appendix A.
Source: Tetra Tech, Inc.
Figure 5-1. View of Willow Street (top) and an artist's rendering of the greenstreet design (bottom)
24
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5.1 Stormwater Management Calculations
In order to develop a properly sized conceptual design, calculations (or detailed assumptions) are
required. For this project, the hydraulic modeling effort described in Section 4 of this report provided all
of the necessary input values for designing the conventional and green infrastructure practices that
were analyzed. As a result, these calculations will not be described again here.
5.2 Cost Estimates
In order to provide a basis for cost-effectiveness of the various solutions identified for the Willow Street
catchment area, planning level implementation cost estimates were developed for each of the modelled
scenarios. For the centralized infiltration and distributed bioretention practices contained in scenario's
1A, IB, and 3, costs were derived using unit cost values reported by King and Hagen (2011) who
estimate cost on a per acre treated basis. Costs for Scenario 2 (stormwater diversion) were estimated
using bid summary results provided by City staff from similar work recently completed in the City.
Since the 12 distributed bioretention systems were all undersized relative their typical design criteria,
their reported contributing areas are not appropriate for use in determining unit costs. To address this
issue, the actual contributing area for each bioretention practice were adjusted relative to the percent
of the 1 inch runoff volume each practice captured and treated. This adjustment normalized the
drainage area to a more appropriate unit cost basis. A drainage area adjustment was not necessary for
the infiltration practices, as they were sized generally according to standard sizing criteria.
A summary of implementation costs for these Scenarios is provided in Table 5-1 and detailed planning
level costs for each scenario are provided in Appendix B.
Table 5-1. Summary of planning level implementation costs
Scenario
Implementation Costs
Scenario 1A Centralized Infiltration w/o check valve
$145,531
Scenario 1B Centralized Infiltration with check valve
$149,531
Scenario 2 Stormwater Separation
$164,032
Scenario 3 Distributed Bioretention
$138,110
25
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6 Conclusion
The project team sought to explore the use of green infrastructure as a way to reduce stormwater flows
causing nuisance flooding and frequent combined sewer overflows in the historic Willow Street
Catchment area. The project team identified roadside bioretention areas as the most suitable green
infrastructure practice for the neighborhood and identified numerous locations throughout the
catchment area where these practices could be integrated into the community with minimal impact on
existing infrastructure and other community needs. However, older established neighborhoods such as
Willow Street often exhibit limited opportunities to retrofit green infrastructure practices.
To supplement the proposed bioretention measures, the project team identified potential options for
conventional stormwater diversion and centralized hybrid green-gray approaches to stormwater
management, including underground infiltration and surface infiltration swales. Long-term simulation
using a hydraulic stormwater model of the catchment area revealed that each of the identified
solutions, both green and grey, would individually reduce the frequency but not eliminate CSOs. To
optimize a reduction in flooding and CSOs in the Willow Street catchment area, the city of Bath may
consider a combination of practices which incorporate both green and conventional infrastructure.
26
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7 References
City of Bath. 2014. City of Bath municipal website. htto://www.citvofbath.com/.
James, W., W.C. Huber, R.E. Dickinson, R.E. Pitt, R.C. James, L.A. Roesner, and J.A. Aldrich. 2005. Water
Systems Models: User's Guide to SWMM, 10th edition. Computational Hydraulics International.
Guelph, Ontario. 802 pages.
King, D. and P. Hagen. 2011. Costs of Stormwater Management Practices in Maryland Counties.
University of Maryland Center for Environmental Science, Solomons, MD.
Rossman, L.A. 2010. Stormwater Management Model User's Manual Version 5.0. EPA/600/R-05/040.
U.S. Environmental Protection Agency, Water Supply and Water Resources Division, National
Risk Management Research Laboratory. Cincinnati, OH.
US Census. 2010. United States Census Bureau, 2010 Census. Community Facts for Bath Maine.
htto://fact fin der2. census, aov/faces/nav/ist/pages/community facts.xhtml.
27
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Appendix A: Willow Street Greenstreet Concept Design
28
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Site Location
Drainage Area Characteristics Proposed Characteristics*
Date of Field Visit
Field Visit Personnel
Major Watershed
Catchment Area
8/14/2014
J. Smith
Kennebec River
Willow Street
Catchment Area
Latitude
longitude
43" 55' 12" N
69*48' 57" W
Multiple private and
Gty owned ROW
Drainage Afea, acres
HydrologicSoil Group
Total Impervious, %
Design Sto'm Event in
45.3
D, Urban
32
LO
Proposed BMPs
Treated drainage area,
acres
Bioretention Area, ft2
Estimated Cost
BR
9.0
4,276
$138,110
Existing Site Description: The proposed project site Includes the Willow Street
catchment area. The area is a residential neighborhood dating to the early 1800's
with a conventional street network served ay a combined sewer drainage system.
Roadway drainage is routed via curb and gutter into a slotted drain catch basins
located at various locations throughout the watershed.
Proposed Green Infrastructure Description: Twelve locations were identified for
the implementation of bioretention planter boxes within the existing roadway.
Retrofit locations were identified based! on existence of curb edge catch basins,
local topography and relative absence of conflicts such as utilities, trees, and
adjacent structural elements.
= Ekgrrtemtorn
"Green Infrastructure chdraclaaia are based an Ma ctEe/vJlionj and CIS data resourofii nvaiaUe M the t*ne Of
wooephj-ai design aniysii Note thai mat deign characteristics we be dependent on a daUHetf s4e survey and could
wiy rtghlty frcm concejuui design charactered^
Project Site Drainage Area
Bath City Limits
£ 73
m m p
522
E2
O
o
^ i
> m
CD CO m
TO 70
CO
O
o
o
3L
~ 20
ro ^ m
o Q ^
73 S 5
^ m S
sgss
^ c 00
TJ
f,
/li Wright Or
vA&ta
Vğ '.VV. .v v|f tA
f-% - if
Legend
Boretention Locations
O CatchBasin
SSWR Lines
StormDrain
Proposed Bioretention Locations
7
Current Street View
Conceptual Bioretention Rendering
"rawswrg on te
TTfa
Typical Cross-section
Bioretention Planter Schematic
ffl
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Appendix B: Willow Street Greenstreet Concept Cost Estimates
The following tables contain the detailed cost estimates for the information presented in Section 5.
Table I. Cost estimate for Scenario I (Centralized Infiltration Systems)
Item No.
Description
Reference
Quantity
Unit
Unit Cost
Total
Pre-const ruction
1
Survey, design, permitting, etc.3
King and Hagen,
2011
1.9
ac
$16,700.00
$31,985
Construction
2
Capital, labor, materials,
overhead3
King and Hagen,
2011
1.9
ac
$41,750.00
$79,962
Construction Subtotal
$111,947
3
Construction contingency (30% of subtotal)
$33,584
Total Cost
Scenario 1A
$145,531
Total Cost
Scenario1Bb
$149,531
a. Categorized as "Infiltration Practices w/o Sand, Veg"
b. $4,000 added to construction subtotal to account for additional check valve
Table 2. Cost Estimate for Scenario 2 (Storm Sewer Diversion)
Item No.
Description
Reference
Quantity
Unit
Unit Cost
Total
Preparation
1
Traffic Control
Bid Tab
8
day
$1,000.00
$7,500
Storm Sewer Installation
2
Furnish and Install 12" Storm Drain
Bid Tab 12898A
775
LF
$85.00
$65,875
3
Furnish and Install Catch Basin
Bid Tab 12898A
2
EA
$3,000.00
$6,000
4
Furnish and install aggregate base
Bid Tab 12898A
24
CY
$65.00
$1,555
5
Furnish and install aggregate sub-base
Bid Tab 12898A
47
CY
$55.00
$2,605
6
Furnish and install HMA 12.5 mm
Bid Tab 12898A
93
TN
$110.00
$10,198
Construction Subtotal
$93,733
7
Estimating Contingency (30% of subtotal)
$28,120
8
Planning (20% of subtotal)
$18,747
9
Mobilization (10% of subtotal)
$9,373
10
Construction contingency (15% of subtotal)
$14,060
Total Cost
$164,032
29
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Table 3. Cost Estimate for Scenario 3 (Distributed Bioretention)
Item No.
Description
Reference
Quantity
Unit
Unit Cost
Total
Pre-construction
1
Survey, design, permitting, etc.3
King and Hagen,
2011
0.6
ac
$52,500.00
$30,354
Construction
2
Capital, labor, materials,
overhead3
King and Hagen,
2011
0.6
ac
$131,250.00
$75,884
Construction Subtotal
$106,238
3
Construction contingency (30% of subtotal)
$31,871
Total Cost
$138,109
a. Categorized as "Bioretention (Retrofit-Highly Urban)"
30
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