HomeMy WebLinkAboutCT 00-02; CALAVERA HILLS VILLAGE Y; STORMWATER MANAGEMENT PLAN; 2003-07-07STORMWATER MANAGEMENT PLAN
FOR
VILLAGE 'Y'
FOR
CALAVERA HILLS
CARLSBAD TRACT 00-02
Carlsba(d, California
Water Discharge Identification No.
July 7, 2003
PREPARED BY
O'Day Consultants, Inc.
2710 Loker Avenue West, Suite 100
Carlsbad, CA 92008
(760)931-7700
981020
Table of Contents
Vicinity Map 3
Drainage Study 4
Project Description 4
Pollutants and Conditions of Concem 4
Site Design BMPs 5
Source Control BMPs 5
Structural Treatment BMPs 6
Maintenance 7
Appendices
Appendix A - Village ' Y' Post Construction BMP Summary Sheet
Appendix B - Selected Source Control BMPs
Appendix C - Selected Treatment Control BMPs
Appendix D - Bioclean Environmental Services, Inc.
Grate Inlet Skimmer Box, Curb Inlet Basket, Nutrient Baffle Box
Report & Data
Appendix E - Drainage Study for Calavera Hills-Village 'X'
Appendix F - Hydrology Study for Calavera Hills Village ' Y'
Appendix G - Excerpt of Declaration of Restrictions for Calavera Hills II Planned
Development
Appendix H - Excerpt of Calavera Hills II Resource Agency Permits-Regional Water
Quality Control Board Order No. R98-2002-0014 Waste Discharge
Requirements and Section 401 Certification Dated February 13, 2002
Appendix I - Sample Water Quality Pamphlets
W:\MSOFFICE\WINWORD\981020\Village Y SWMP Rpt.doc
VICINITY MAP
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CITY OF ENCINITAS
VILLAGE r
PREPARED BY ODAY CONSULTANTS, INC Gi\SDSK\PRaj\9810aO\BWG\CALAVERA\98eOXVHBVG 7-8-2003 10ieei46 an
Drainage Study
There appeared to be no drainage concems downstream of the site at the time of
investigation.
Project Description
The proposed condition for Village Y will be a 9.40-acre multi-family residential and
community facilities sub-division. 6.94 acres of the project site will be developed. 0.97
acres of the developed area will be mass graded for fiature community facilities
development. The remaining 2.46 acres will remain in its existing condition.
6.36 acres of the development will be conveyed southerly through stormwater drainage
pipes towards a cul-de-sac on Village "X" and discharged into a stormwater drainage
system within the adjacent development. These flows are then combined with a portion
of Village "X" stormwater mnoff and ultimately discharged into an extended detention
basin located at the northwesterly comer of Village "X". 0.58 acres of the developed
6.36 acres will be a mass-graded pad for future community facilities development while
the remaining 5.78 acres will be multi-family residential development.
0.58 acres of Village "Y" development, northerly portion, will be discharged northerly
into College Boulevard's stormwater drainage system. Surface mnoff generated from
this area will flow southeasterly along College Boulevard. 0.38 acres of this developed
area will be a mass-graded pad for the fiiture community facilities development. The
remaining 0.20 acres will be a portion of the private road accessing College Boulevard.
Pollutants and Conditions of Concern
The anticipated and potential pollutants that will be generated by this project was
determined using Table 2 of the Storm Water Standards. The following are potential and
anticipated pollutants for this project:
• Sediments • "
• Nutrients
• Trash and Debris
• Oxygen Demanding Substances
• Oil and Grease
• Bacteria and Vimses
• Pesticides
Organic compounds are considered potential pollutants if the community facilities
development includes uncovered parking areas, but the extent of the community facilities
pad's friture development is undetermined at this point.
There are no additional conditions of concems identified at this time.
Site Design BMPs
The BMPs selected for this project were based on the Regional Water Quality Control
Board Order No. R98-2002-0014 Waste Discharge Requirements and Section 401
Certification Dated Febmary 13, 2002 and its exhibit Attachment 1 (See Appendix H for
an excerpt of the Calavera Hills II Resource Agency Permit Report).
The post constmction BMP's that will be used for this project will be addressed on the
following paragraphs.
Several Site Design BMPs will be used on this project site. See Appendix B for
additional information on the selected Site Design BMPs.
The following Site Design BMPs will be implemented in order to minimize impervious
areas:
• A total of six feet wide landscaped buffer will be incorporated within the
general utility and access easements with the site.
• A total of eleven feet wide landscaped buffer will be incorporated within
some areas of Red Bluff Place general utility and access easement.
The developer will install the pavement, sidewalk and landscape buffer.
All exposed earth will be hydroseeded or landscaped per the Village Y's landscape plans
and will be installed by the developer.
The developed site will be irrigated to maintain all vegetation and will be installed by the
developer.
Source Control BMPs
The following Source Control BMPs will be incorporated to the site:
• All stormwater curb inlets will be stamped with thermoplastic letterings
"No Dumping - I Live Downstream"
Curb inlet stamps will be placed on all curb inlets onsite and will be placed by the
developer.
Water quality educational pamphlets will also be sent to tenants and contractors. The
developers will be responsible for ensuring the contractors receive the pamphlets prior to
constmction. The homeowner's association will be responsible for sending these
educational pamphlets to all new tenants and once a year. See Appendix I for sample
pamphlets.
Mechanical sweeping shall be used to clean the street. Street sweeping shall be done
twice a month and the homeowner's association will provide the service.
Trash storage areas will be installed by the contractor and built per City of Carlsbad
standard drawings.
Structural Treatment BMPs
Storm drainage inserts and an extended detention basin will be used for Stmctural
Treatment BMPs.
The drainage inserts will be Curb Inlet Baskets. The drainage inserts are Suntree
Technologies Inc. products. See Appendix D for product information.
The extended detention basin will be located at the southwesterly comer of the Village
"X" development. This basin will be used to detain and treat portions of Village "X" and
Village "Y" developments. The other portions of Village "X" and "Y" will be
discharged into the storm drainage system along College Boulevard.
The total required volume for the extended detention basin was determined as follows:
V = C*P24*(1 ft/12 in)*A*(43560 sf/1 ac)
Where,
V = Volume in cubic feet
C = Runoff coefficient (See Appendix E and F for coefficients used)
P24 = 24-hour 85* percentile storm event (0.6 inches)
A = Area to be detained in acres (See Appendix E and F for areas used)
The required volume for Village 'X' was determined as follows:
Required volume for the 2.56-acre open space:
V = 0.45*0.6*1/12*2.56*43560 = 2509 cf
Required volume for the single-family development area:
A V-0.55*0.6*1/12*6.16*43560 = 7379 cf
The required volume for Village 'Y' was determined as follows:
Required volume for the community facilities area:
V = 0.85*0.6*1/12*0.59*43560 = 1092 cf
Required volume for the multi-family development area:
V = 0.70*0.6*1/12*5.77*43560 = 9889 cf
The total required volume for the extended detention basin is approximately 20,869. The
extended detention basin will provide approximately 25,200 cubic feet of live storage.
The drainage inserts and extended detention basins will reduce the following pollutants
from entering downstream:
• Oxygen Demanding Substances
• Nitrate and Nitrite
• Nitrogen
• Oil and Grease
• Phosphate
• Solids
Maintenance
The post constmction BMP's will be maintained as follows (See Village 'Y' Post
Constmction BMP Summary Sheet in Appendix A for BMP maintenance information):
Streetsweeping: Homeowner's Association
Catch Basin Inserts: Homeowner's Association
Extended Detention Basin: Homeowner's Association
Inlet Basin Labeling: Homeowner's Association
Landscaping: Homeowner's Association
Irrigation: Homeowner's Association
The maintenance ofthese BMP's is in conformance with Attachment 1 ofthe Regional
Water Quality Control Board Order No. R98-2002-0014 Waste Discharge Requirements
and Section 401 Certification Dated Febmary 13, 2002 (See Appendix H).
Additional maintenance requirements are addressed on Article X Maintenance
Responsibilities of the Declaration of Restrictions for Calavera Hills II Planned
Development. See Appendix G for j^rticle X.
Site Pesign & Landscape Planning SD-10
Design Objectives
•
•
Maximize Infiltration
Provide Retention
Slow Runoff
iVlinimize Impervious Land
Coverage
Prohibit Dumping of Improper
Materials
Contain Pollutants
Collect and Convey
Description
Each project site possesses unique topographic, hydrologic, and vegetative features, some of
which are more suitable for development than others. Integrating and incorporating
appropriate landscape planning methodologies into the project design is the most effective
action that can be done to minimize surface and groundwater contamination from stormwater.
Approach
Landscape planning should couple consideration of land suitability for urban uses with
consideration of community goals and projected growth. Project plan designs should conserve
natural areas to the extent possible, maximize natural water storage and infiltration
opportunities, and protect slopes and channels.
Suitable Appiications '
Appropriate applications include residential, commercial and industrial areas planned for
development or redevelopment.
Design Considerations
Design requirements for site design and landscapes planning should conform to applicable
standards and specifications of agencies with jurisdiction and be consistent with applicable
General Plan and Local Area Plan policies.
,C A S Q A
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Stormwater
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January 2003 California Stormwater BMP Handbook
New Development and Redevelopment
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SD-10 Site Design & Landscape Planning
Designing Neiv Installations
Begin the development of a plan for the landscape unit with attention to the following general
principles:
• Formulate the plan on the basis of clearly articulated community goals. Carefully identify
conflicts and choices between retaining and protecting desired resources and community
growth.
• Map and assess land suitability for urban uses. Include the following landscape features in
the assessment: wooded land, open unwooded land, steep slopes, erosion-prone soils,
foundation suitability, soil suitability for waste disposal, aquifers, aquifer recharge areas,
wetlands, floodplains, surface waters, agricultural lands, and various categories of urban
land use. When appropriate, the assessment can highlight outstanding local or regional
resources that the community determines should be protected (e.g., a scenic area,
recreational area, threatened species habitat, farmland, fish run). Mapping and assessment
should recognize not only these resources but also additional areas needed for their
sustenance.
Project plan designs should conserve natural areas to the extent possible, maximize natural
water storage and infiltration opportunities, and protect slopes and channels.
Conserve Natural Areas during Landscape Planning '
If applicable, the following items are required and must be implemented in the site layout
during the subdivision design and approval process, consistent with applicable General Flan and
Local Area Flan policies:
• Cluster development on least-sensitive portions of a site while leaving the remaining land in
a natural undisturbed condition.
B Limit clearing and grading of native vegetation at a site to the minimum amount needed to
build lots, allow access, and provide fire protection.
• Maximize trees and other vegetation at each site by planting additional vegetation, clustering
tree areas, and promoting the use of native and/or drought tolerant plants.
• Promote natural vegetation by using parking lot islands and other landscaped areas.
• Preserve riparian areas and wetiands.
Maximize Natural Water Storage and Infiltration Opportunities Within the Landscape Unit
m Promote the conservation of forest cover. Building on land that is already deforested affects
basin hydrology to a lesser extent than converting forested land. Loss of forest cover reduces
interception storage, detention in the organic forest floor layer, and water losses by
evapotranspiration, resulting in large peak runoff increases and either their negative effects
or the expense of countering thern with structural solutions.
• Maintain natural storage resei-voirs and drainage corridors, including depressions, areas of
permeable soils, swales, and intermittent streams. Develop and implement poiicies and
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Site Design & Landscape Planning SD-10
regulations to discourage the clearing, filling, and channelization of these features. Utilize •
them in drainage networks in preference to pipes, culverts, and engineered ditches.
• Evaluating infiltration opportunities by referring to the stormwater management manual for
the jurisdiction and pay particular attention to the selection criteria for avoiding
groundwater contamination, poor soils, and hydrogeological conditions that cause these
facilities to fail. If necessary, locate developments with large amounts of impervious
surfaces or a potential to produce relatively contaminated runoff away from groundwater
recharge areas.
Protectionof Slopes and Channels during Landscape Design
• Convey runoff safely from the tops of slopes.
• Avoid disturbing steep or unstable slopes. '
• Avoid disturbing natural channels.
• Stabilize disturbed slopes as quickly as possible.
• Vegetate slopes with native or drought tolerant vegetation.
• Control and treat flows in landscaping and/or other controls prior to reaching existing
natural drainage systems.
• Stabihze temporary and permanent channel crossings as quickly as possible, and ensure that
increases in run-off velocity and frequency caused by the project do not erode the channel.
• Install energy dissipaters, such as riprap, at the outlets of new storm drains, culverts,
conduits, or channels that enter unlined channels in accordance with applicable
specifications to minimize erosion. Energy dissipaters shall be installed in such a way as to
minimize impacts to receiving waters.
• Line on-site conveyance channels where appropriate, to reduce erosion caused by increased
flow velocity due to increases in tributary impervious area. The first choice for linings
should be grass or some other vegetative surface, since these materials not only reduce
runoff velocities, but also provide water quality benefits from filtration and inflitration. If
velocities in the channel are high enough to erode grass or other vegetative linings, riprap,
concrete, soil cement, or geo-grid stabilization are other alternatives.
• Consider other design principles that are comparable and equally effective.
Redeveloping Existing Installations
Variousjurisdictional stormwater management and mitigation plans (SUSMP, WQMP, etc.)
define "redevelopment" in terms of amounts of additional impervious area, increases in gross
floor area and/or exterior constmction, and land disturbing activities with structural or
impervious surfaces. The definition of" redevelopment" must be consulted to determine
whether or not the requirements for new development apply to areas intended for
redevelopment. Ifthe definition apphes, the steps outhned under "designing new installations"
above should be followed.
January 2003 California Stormwater BMP Handbook
New Development and Redevelopment
www.cabmphandbooks.com
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SD-10 Site Design & Landscape Planning
Redevelopment may present significant opportunity to add features which had not previously
been implemented. Examples include incorporation of depressions, areas of permeable soils,
and swales in newly redeveloped areas. While some site constraints may exist due to the status
of already existing infrastmcture, opportunities should not be missed to maximize infiltration,
slow runoff, reduce impervious areas, disconnect directly connected impervious areas.
Other Resources
A Manual for the Standard Urban Stormwater Mitigation Plan (SUSMP), Los Angeles County
Department of PubUc Works, May 2002.
Stormwater Management Manual for Western Washington, Washington State Department of
Ecology, August 2001.
Model Standard Urban Storm Water Mitigation Plan (SUSMP) for San Diego County, Port of
San Diego, and Cities in San Diego County, February 14, 2002.
Model Water Quality Management Plan (WQMP) for County of Orange, Orange County Flood
Control District, and the Incorporated Cities of Orange County, Draft February 2003.
Ventura Countywide Technical Guidance Manual for Stormwater Quality Control Measures,
July 2002.
4 of 4 California Stormwater BMP Handbook January 2003
New Development and Redevelopment
www.cabmphandbooks.com
Roof Runoff Controls SD-11
Design Objectives
yf Maximize Infiltration
•/ Provide Retention
y Slow Runoff
Minimize Impervious Land
Coverage
Prohibit Dumping of Improper
Materials
•/ Contain Pollutants
Collect and Convey
Rain Garden
Description ' • ' - '
Various roof runoff controls are available to address stormwater
that drains off rooftops. The objective is to reduce the total volume and rate of runoff from
individual lots, and retain the pollutants on site that may be picked up from roofing materials
and atmospheric deposition. Roof runoff controls consist of directing the roof runoff away from
paved areas and mitigating flow to the storm drain system through one of several general
approaches: cisterns or rain barrels; dry wells or infiltration trenches; pop-up emitters, and
foundation planting. The first three approaches require the roof runoff to be contained in a
gutter and downspout system. Foundation planting provides a vegetated strip under the drip
line ofthe roof.
Approach • ' s- .f. •
Design of individual lots for single-family homes as well as lots for higher density residential and
commercial structures should consider site design provisions for containing and infiltrating roof
runoff or directing roof runoff to vegetative swales or buffer areas. Retained water can be reused
for watering gardens, lawns, and trees. Benefits to the environment include reduced demand for
potable water used for irrigation, improved stormwater quality, increased groundwater
recharge, decreased runoff volume and peak flows, and decreased flooding potential.
Suitable Applications
Appropriate applications include residential, commercial and industrial areas planned for
development or redevelopment.
Design Considerations
Designing New Installations
Cisterns or Rain Barrels
One method of addressing roof runoff is to direct roof downspouts
to cisterns or rain barrels. A cistern is an above ground storage
vessel with either a manually operated valve or a permanently open
outlet. Roof runoff is temporarily stored and then released for
irrigation or infiltration between storms. The number of rain
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January 2003 California Stormwater BMP Handbook
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SD-11 Roof Runoff Controls
barrels needed is a function of the rooftop area. Some low impact developers recommend that
eveiy house have at least 2 rain barrels, with a minimum storage capacity of iooo liters. Roof
barrels serve several purposes including mitigating the first flush from the roof which has a high
volume, amount of contaminants, and thermal load. Several types of rain barrels are
commercially available. Consideration must be given to selecting rain barrels that are vector
proof and childproof. In addition, some barrels are designed with a bypass valve that filters out
grit and other contaminants and routes overflow to a soak-away pit or rain garden.
If the cistern has an operable valve, the valve can be closed to store stormwater for irrigation or
infiltration between storms. This system requires continual monitoring by the resident or
grounds crews, but provides greater flexibility in water storage and metering. If a cistern is
provided with an operable valve and water is stored inside for long periods, the cistern must be
covered to prevent mosquitoes from breeding.
A cistern system with a permanently open outlet can also provide for metering stormwater
runoff. If the cistern outlet is significantly smaller than the size of the dovmspout inlet (say VA to
V2 inch diameter), runoff will build up inside the cistern during storms, and will empty out
slowly after peak intensities subside. This is a feasible way to mitigate the peak flow increases
caused by rooftop impervious land coverage, especially for the frequent, small storms.
Dry wells and Infiltration Trenches
Roof downspouts can be directed to dry wells or inflitration trenches. A dry well is constructed
by excavating a hole in the ground and filling it with an open graded aggregate, and allowing the
water to fill the dry well and infiltrate after the storm event. An underground connection from
the downspout conveys water into the dry well, allowing it to be stored in the voids. To
minimize sedimentation from lateral soil movement, the sides and top of the stone storage
matrix can be wrapped in a permeable filter fabric, though the bottom may remain open. A
perforated observation pipe can be inserted vertically into the dry well to allow for inspection
and maintenance.
In practice, dry wells receiving mnoff from single roof downspouts have been successful over
long periods because they contain very little sediment. They must be sized according to the
amount of rooftop runoff received, but are typically 4 to 5 feet square, and 2 to 3 feet deep, with
a minimum of i-foot soil cover over the top (maximum depth of 10 feet).
To protect the foundation, dry wells must be set away from the building at least 10 feet. They
must be installed in solids that accommodate infiltration. In poorly drained soils, dry wells have
very limited feasibility.
Infiltration trenches function in a similar manner and would be particularly effective for larger
roof areas. An infiltration trench is a long, narrow, rock-filled trench with no outlet that receives
stormwater runoff. These are described under Treatment Controls.
Pop-up Drainage Emitter
Roof downspouts can be directed to an underground pipe that daylights some distance from the
building foundation, releasing the roof mnoff through a pop-up emitter. Similar to a pop-up
irrigation head, the emitter only opens when there is flow from the roof The emitter remains
flush to the ground during dry periods, for ease of lawn or landscape maintenance.
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Roof Runoff Controls SD-11
Foundation Planting
Landscape planting can be provided around the base to allow increased opportunities for
stormwater infiltration and protect the soil from erosion caused by concentrated sheet flow
coming off the roof Foundation plantings can reduce the physical impact of water on the soil
and provide a subsurface matrix of roots that encourage infiltration. Tiiese plantings must be
sturdy enough to tolerate the heavy runoff sheet flows, and periodic soil saturation.
Redeveloping Existing InstaUations
Various jurisdictional stormwater management and mitigation plans (SUSMP, WQMP, etc.)
define "redevelopment" in terms of amounts of additional impervious area, increases in gross
floor area and/or exterior construction, and land disturbing activities with structural or
impervious surfaces. The definition of " redevelopment" must be consulted to determine
whether or not the requirements for new development apply to areas intended for
redevelopment. If the definition applies, the steps outlined under "designing new installations"
above should be followed.
Syppiemental Information . \ •
Examples
• City of Ottawa's Water Links Surface -Water Quality Protection Program
a City ofToronto Dovmspout Disconnection Program
• City of Boston, MA, Rain Barrel Demonstration Program
Other Resources
Hager, Marty Catherine, Stormwater, "Low-Impact Development", January/February 2003.
www.stormh2o.com
Low Impact Urban Design Tools, Low Impact Development Design Center, Beltsville, MD.
www.lid-stormwater.net
Start at the Source, Bay Area Stormwater Management Agencies Association, 1999 Edition
January 2003 California Stormwater BMP Handbook 3 of 3
New Development and Redevelopment
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Efficient Irrigation SD-12
Design Objectives
•</ Maximize Infiltration
yf Provide Retention
y Slow Runoff
Minimize Impervious Land
Coverage
Prohibit Dumping of Improper
Materials
Contain Pollutants
Collect and Convey
Description
Irrigation water provided to landscaped areas may result in excess irrigation water being
conveyed into stormwater drainage systems.
Approach
Project plan designs for development and redevelopment should include application methods of
irrigation water that minimize runoff of excess irrigation water into the stormwater conveyance
system. \ . -
Suitable Applications
Appropriate applications include residential, commercial and industrial areas planned for
development or redevelopment. (Detached residential single-family homes are typically
excluded from this requirement.)
Design Considerations v
Designing New Installations
The following methods to reduce excessive irrigation runoff should be considered, and
incoi-porated and implemented where determined applicable and feasible by the Permittee:
• Employ rain-triggered shutoff devices to prevent irrigation after precipitation.
• Design irrigation systems to each landscape area's specific water requirements.
• Include design featuring flow reducers or shutoff valves triggered by a pressure drop to
control water loss in the event of broken sprinkler heads or lines.
• Implement landscape plans consistent with County or Cit>' water conservation resolutions,
which may include provision of water sensors, programmable
irrigation times (for short cycles), etc. ^^4C A S O A
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Stormwater
Quality
Association
January 2003 California Stormwater BMP Handbook
New Development and Redevelopment
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SD-12 Efficient Irrigation
m Design timing and application methods of irrigation water to rniriimize the nmoff of excess
irrigation water into the storm water drainage system. ..
• Group plants with similar water requirements in order to reduce excess irrigation runoff and
promote surface filtration. Choose plants wdth iow irrigation requirements (for example,
native or drought tolerant species). Consider design Itatiires such as:
Using mulches (such as wood chips or bar) in planter areas without ground cover to
minimize sediment in runoff
Installing appropriate plant materials for the location, in accordance with amount of
sunlight and climate, and use native plant materials where possible and/or as
recommended by the landscape architect
Leaving a vegetative barrier along the propeity boundary and interior watercourses, to
act as a pollutant filter, where appropriate and feasible
Choosing plants that minimize or eliminate the use of fertilizer or pesticides to sustain
growth
m Employ other comparable, equally effective methods to reduce irrigation water mnoff.
Redeveloping Existing Installations :V
Various jurisdictional stormwater management and mitigation plans (SUSMP, WQMP, etc.)
define "redevelopment" in terms of amounts of additional impervious area, increases in gross
floor area and/or exterior construction, and land disturbing activities with structural or
impervious surfaces. The definition of " redevelopment" must be consulted to determine
whether or not the requirements for new development apply to areas intended for
redevelopment. If the definition applies, the steps outlined under "designing new installations"
above should be followed.
Other Resources
A Manual for the Standard Urban Stormwater Mitigation Plan (SUSMP), Los Angeles County
Department of Public Works, May 2002.
Model Standard Urban Storm Water Mitigation Plan (SUSMP) for San Diego County, Port of
San Diego, and Cities in San Diego County, February 14, 2002.
Model Water Quality Management Plan (WQMP) for County of Orange, Orange County Flood
Control District, and the Incorporated Cities of Orange County, Draft February 2003.
Ventura Count)wide Technical Guidance Manual for Stormwater Quality Control Measures,
July 2002.
2 of 2 California Stormwater BMP Handbook January 2003
New Development and Redevelopment
www.cabmphandbooks.com
storni Drain Signage SD-13
Design Objectives
Maximize Infiltration
Provide Retention
Slow Runoff
i Minimize Impervious Land
Coverage
y Prohibit Dumping of Improper
Materials
Contain Pollutants
Collect and Convey
Description • ' •
Waste materials dumped into storm drain inlets can have severe impacts on receiving and
ground waters. Posting notices regarding discharge prohibitions at storm drain inlets can
prevent waste dumping. Storm drain signs and stencils are highly visible source controls that
are typically placed directly adjacent to storm drain inlets.
Approach ... . .. ^
The stencil or affixed sign contains a brief statement that prohibits dumping of improper
materials into the urban runoff conveyance system. Storm drain messages have become a
popular method of alerting the public about the effects of and the prohibitions against waste
disposal.
Suitable Applications
Stencils and signs alert the public to the destination of pollutants discharged to the storm drain.
Signs are appropriate in residential, commercial, and industrial areas, as well as any other area
where contributions or dumping to storm drains is likely.
Oesign Considerations
Storm drain message markers or placards are recommended at all storm drain inlets within the
boundary of a development project. The marker should be placed in clear sight facing toward
anyone approaching the inlet from either side. All storm drain inlet locations should be
identified on the development site map.
Designing New Installations
The following methods should be considered for inclusion in the project design and show on
project plans:
Provide stenciling or labeling of all storm drain inlets and catch
basins, constructed or modified, within the project area with
prohibitive language. Examples include "NO DUMPING -California
Stormwater
Quality
Association
January 2003 California Stormwater BMP Handbook
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SD-13 storm Drain Signage
DRAINS TO OCEAN " and/or other graphical icons to discourage illegal dumping.
• Post signs with prohibitive language and/or graphical icons, which prohibit illegal dumping
at public access points along channels and creeks within the project area.
Note - Some local agencies have approved spedfic signage and/or storm drain message placards
for use. Consult local agency stormwater staff to determine specific requirements for placard
types and methods of apphcation.
Redeveloping Existing Installations
Various jurisdictional stormwater management and mitigation plans (SUSMP, WQMP, etc.)
define "redevelopment" in terms of amounts of additional impei-vious area, increases in gross
floor area and/or exterior construction, and land disturbing activities with structural or
impei-vious surfaces. If the project meets the definition of "redevelopment", then the
requirements stated under " designing new installations" above should be included in all project
design plans.
Additional Information
Maintenance Considerations ••
m Legibility of markers and signs should be maintained. If required by the agency with
jurisdiction over the project, the owner/operator or homeowner's association should enter
into a maintenance agreement with the agency or record a deed restriction upon the
property titie to maintain the legibility of placards or signs.
Placement
m Signage on top of curbs tends to weather and fade.
a Signage on face of curbs tends to be worn by contact with vehicle tires and sweeper brooms.
Supplemental Information
Examples
B Most MS4 programs have storm drain signage programs. Some MS4 programs will provide
stencils, or arrange for volunteers to stencil storm drains as part of their outreach program.
Other Resources
A Manual for the Standard Urban Stormwater Mitigation Plan (SUSMP), Los Angeles County
Department of Public Works, May 2002.
Model Standard Urban Storm Water Mitigation Plan (SUSMP) for San Diego County, Port of
San Diego, and Cities in San Diego County, February 14, 2002.
Model Water Quality Management Plan (WQMP) for County of Orange, Orange County Flood
Control District, and the Incorporated Cities of Orange County, Draft February 2003.
Ventura Countywide Technical Guidance Manual for Stormwater Quality Control Measures,
July 2002.
2 of 2 California Stormwater BMP Handbook January 2003
New Development and Redevelopment
www.cabmphandbooks.com
Drain Inserts
Description
Drain inserts are manufactured filters or fabric placed in a drop
inlet to remove sediment and debris. There are a multitude of
inserts of various shapes and configurations, typically falhng into
one ofthree different groups: socks, boxes, and trays. The sock
consists of a fabric, usually constructed of polypropylene. The
fabric may be attached to a frame or the grate of the inlet holds
the sock. Socks are meant for vertical (drop) inlets. Boxes are
constructed of plastic or wire mesh. Typically a polypropylene
"bag" is placed in the wire mesh box. The bag takes the form of
the box. Most box products are one box; that is, the setting area
and filtration through media occur in the same box. Some
products consist of one or more trays or mesh grates. The trays
may hold different types of media. Filtration media vary by
manufacturer. Types include polypropylene, porous polymer,
treated cellulose, and activated carbon.
California Experience
The number of installations is unknown but likely exceeds a
thousand. Some users have reported that these systems require
considerable maintenance to prevent plugging and bypass.
Advantages
a Does not require additional space as inserts as the drain
inlets are already a component of the standard drainage
systems.
a Easy access for inspection and maintenance.
a As there is no standing water, there is little concern for
mosquito breeding.
a A relatively inexpensive retrofit option.
Limitations
Performance is likely significantly less than treatment systems
that are located at the end of the drainage system such as ponds
and vaults. Usually not suitable for large areas or areas with
trash or leaves than can plug the insert.
Design and Sizing Guidelines
Refer to manufacturer's guidelines. Drain inserts come any
many configurations but can be placed into three general groups:
socks, boxes, and trays. The sock consists of a fabric, usually
constructed of polypropylene. The fabric may be attached to a
frame or the grate of the inlet holds the sock. Socks are meant
for vertical (drop) inlets. Boxes are constructed of plastic or wire
mesh. Typically a polypropylene "bag" is placed in the wire mesh
box. The bag takes the form of the box. Most box products are
Design Considerations
a Use with other BMPs
a Fit and Seal Capacity within Inlet
Targeted Constituents
V Sediment
yY Nutrients
yY Trash -
yY Metals
Bacteria
y Oil and Grease
yY Organics
Removal Effectiveness
See New Development and
Redevelopment Handbook-Section 5.
Caiifomla
Stormwater
Quality
Association
January 2003 California Stormwater BMP Handbook
New Development and Redevelopment
www.cabmphandbooks.com
1 of 3
MP-52 Drain Inserts
one box; that is, the setting area and filtration through media occurs in the same box. One
manufacturer has a double-box. Stormwater enters the first box where setting occurs. The
stormwater flows into the second box where the filter media is located. Some products consist
of one or more trays or mesh grates. The trays can hold different types of media. Filtration
media vary with the manufacturer: types include polypropylene, porous polymer, treated
cellulose, and activated carbon.
Construction/Inspection Considerations
Be certain that installation is done in a manner that makes certain that the stormwater enters
the unit and does not leak around the perimeter. Leakage between the frame of the insert and
the frame of the drain inlet can easily occur with vertical (drop) inlets. ;
Performance
Few products have performance data collected under field conditions.
Siting Criteria
It is recommended that inserts be used only for retrofit situations or as pretreatment where
other treatment BMPs presented in this section area used. -'
Additional Design Guidelines '
Follow guidelines provided by individual manufacturers.
Maintenance
Likely require frequent maintenance, on the order of several times per year.
Cost
m The initial cost of individual inserts ranges from less than $100 to about $2,000. The cost of
using multiple units in curb inlet drains varies with the size ofthe inlet.
B The low cost of inserts may tend to favor the use of these systems over other, more effective
treatment BMPs. However, the low cost of each unit may be offset by the number of units
that are required, more frequent maintenance, and the shorter structural life (and therefore
replacement). ' '
References and Sources of Additional Information
Hrachovec, R., and G. Minton, 2001, Field testing of a sock-type catch basin insert, Planet CPR,
Seattle, Washington
Interagency Catch Basin Insert Committee, Evaluation of Commercially-Available Catch Basin
Inserts for the Treatment of Stormwater Runoff from Developed Sites, 1995
Larry Walker Associates, June 1998, NDMP Inlet/In-Line Control Measure Study Report
Manufacturers literature -
Santa Monica (City), Santa Monica Bay Municipal Stormwater/Urban Runoff Project -
Evaluation of Potential Catch basin Retrofits, Woodward Clyde, September 24,1998
2 of 3 California Stormwater BMP Handbook January 2003
New Development and Redevelopment
www.cabmphandbooks.com
Drain Inserts MP-52
Woodward Clyde, June ii, 1996, Parking Lot Momtoring Report, Santa Clara Valley Nonpoint
Source Pollution Control Program.
January 2003 California Stormwater BMP Handbook
New Development and Redevelopment
www.cabmphandbooks.com
3 of 3
BIO CLEAN
ENVIRONMENTAL SERVICES, INC.
Grate Inlet Skimmer Box
Curb Iniet Basicet
Nutrient Separating Baffle Box
REPORTS & DATA
PoUutant Loading Analysis for Stormwater Retrofitting in
Melboume Beach, Florida
Pollutant Removal Testing for A Suntree Technologies Grate
Inlet SIdmmer Box
Site Evaluation of Suntree Technologies, Inc. Grate Inlet
Skimmer Boxes for Debris, Sediment And Oil & Grease
Removal
BIO CLEAN ENVIRONMENTAL SERVICES, INC.
P O BOX 869, OCEANSIDE, CA 92049
(760) 433-7640 FAX (760) 433-3176
Pollutant Loading Analysis For Stormwater Retrofitting in Melbourne Beach,
Florida
By: Gordon England, P.E.
Creech Engineers, Inc.
4450 W. Eau Gallie Blvd, #232
Melbourne, FI. 32932
Introduction
At Gemini Elementary School in Melbourne Beach, Florida, there has been a history of
repeated flooding on the school grounds and in properties adjacent to the school. In
1999 Creech Engineers, Inc. (CEI) was chosen by Brevard County Stonnwater Utihty to
design drainage improvements to alleviate these flooding conditions, as well as to
provide for stormwater treatment within this 20.06 hectare drainage basin. The project
was divided mto two phases. Phase 1 improvements were made in order to accelerate
initial flood control measures for homes downstream ofthe schooL Phase 2 involved the
design of more extensive flood and water quality control measures along Oak Street for
fiirther protection of school property and roadway flooding at nearby church property.
This paper highlights the political challenges of retrofitting stormwater systems in
developed areas, as well as demonstrates a methodology for performing a nonpoint
source pollutant loading analysis.
Existing Conditions
Gemini Elementary School is located on a 8.02 hectare, triangular shaped property along
the south side of Oak Street, a two lane collector road in Melboume Beach, about one
half mile from the Atlantic Ocean. See Exhibit 1. Residential properties lie downstream
ofthe school, along its southeast and southwest borders. 8.51 hectare Doug Flutie Park is
on the north side of Oak Street. A soccer club uses the park and school grounds on a daily
basis. There was no stormwater system at the park, along Oak Street, or on the school
site. Stormwater flowed southward off Doug Flutie Park, across Oak Street, through the
school site, and into the yards and homes south ofthe school. These yards, and the roads
downstream of them, are very flat and only a few feet above sea level. Once water stages
high enough in the yards, it gradually sheetflows down the adjacent roads a few hundred
yards to the Indian River. The affected homeowners naturaUy blamed the school for
allowing the school's water to flood them.
West ofthe school, a few hundred yards along Oak Street, was a low point in the road
where water ponded and flooded the road and an adjacent churchyard. Due to a thin clay
lens at 26 cm deep causing a perched water table, water stood in the road for several days
after even a nominal rainfall. This drainage basin was ahnost completely built out, with
no easy path for developing outMs to relieve flooding.
This section of the Indian River is a Class 2 v^rater body, with a Shellfish Harvesting
classification bringing intense scrutiny from the St. Johns River Water Management
District. Corp of Engineers permitting is required for new outfalls in the area due to
seagrasses near the shoreline.
The park, the schooL and Oak Street lie in unincorporated Brevard Couniy. The church,
and properties west of the school are in Melboume Beach. Being a collector road, all of
the utility companies have major transmission lines m the road right-of-way.
As can be seen, this challenging project involved Brevard County, Melbourne Beach, the
School Board, Brevard County Parks and Recreation Department, Brevard County Road
and Bridge Department, Brevard County Stormwater Utility, a church, three different
Homeowners Associations, a soccer club, the Water Management District, the Corp of
Engineers, and several utility companies. Stakeholder involvement and partnerships were
going to be critical to weave a solution through the many players involved.
Proposed Improvements
The first priority was to alleviate flooding in the homes adjacent to the school. As an
interim measure, a berm was designed and constmcted by County personnel along the
south property lines of the schooL with a swale behind the berm directing water to the
southernmost point of the school property. At that location, an inlet and 18" outfell pipe
were constmcted in a utility easement through two heavily landscaped and fenced yards,
to Pompano Street, where it was tied into an existing storm drain pipe.
A short time later, heavy rains overflowed the berms and swales and flooded homes
adjacent to the school again. CEI was engaged at that point to provide more effective
drainage improvements.
Fortunately, Gemini Elementary School had a significant area of vacant land on their site.
The school entered into agreements with Brevard County allowing the constmction of
three dry retention ponds totaling 2.95 hectare to reduce flows leaving the school site, as
well as provide stormwater treatment where none existed. These dry ponds were wound
around several soccer and baseball fields. The soccer field's locations had to remain in
place due to previous agreements with the school and Parks and Recreation Dept. The
ponds were only 26-40 cm (12"- 18") deep and sodded, allowing the soccer teams to use
the pond areas as practice fields when dry. When the ponds were excavated, the
confining clay layer was removed to allow for infiltration though the beach sand at the
site. Constmction was scheduled during the summer when school was out.
A control stmcture was designed at the outfall pipe location to provide protection for a 25
year storm. The temporary connection to the existing downstream pipe had overloaded
the downstream system in a heavy rain event, so a new outM to the Indian River was
designed through a park adjacent to the River. The park was owned by a Homeowners
Association, which reluctantly gave a drainage easement through the park. The County
agreed to make several improvements to the park and its boat ramp in exchange for the
easement. The Corp of Engineers was concemed that the new outfell pipe discharges
would unpact the nearby seagrasses, so the new discharge pipe was not permitted to be
constracted in the Indian River. A bubbleup box was designed ten feet back from the
shoreline and rock riprap was placed between the bubbleup box and the mean high water
line to prevent erosion. As mitigation for disturbing the shoreline, spartina and other
plants were planted among the rocks to further buffer the shoreline from the stonnwater
discharges.
This first phase of improvements was finished in September 2000 at a cost of $124,000.
The improvements implemented proved successful in preventing any flooding of adjacent
homes in several large ramfalls in 2001.
The second phase of the project addressed stormwater quantity and quality concems
along 1650 meters of Oak Street, from AIA to Cherry Street. To provide fiirther flood
protection at Gemini Elementary School, retention swales were designed along both sides
of Oak Street and 625 meters of storm drain pipe was designed to intercept runoff and
prevent it from crossing the road onto school property. The piping also provided an
outfall for the low spot m the road by the church.
This new pipe system discharged into a residential canal system, which was used by
many of the adjacent residents for boating to the Indian River Lagoon (Bay). These
canals were very pohtically sensitive since they were in need of dredging and the Town
of Melboume Beach does not dredge canals. The residents were concemed that the new
stormwater system would lead to further sedimentation ofthe canals. The first altemative
for treatment was to use land at the church site for a pond for the road runoff. The church
was willing to donate the land where their septic tank fields were located ifthe County
would provide a sewer connection. This scenario was designed, but when it came time
for the church to give easements to the County, they balked and it was back to the
drawing board.
St. Johns River Water Management District, (District), criteria requires stonnwater
treatment for improvements wiiich a) increase discharge rates b) which increase pollutant
loadings, or c) which mcrease impervious areas. With this project, no new mcreased
impervious areas were proposed, but there would be additional water flowing to the
residential canal from the extension of the pipe system to the flood prone areas. These
new flows create the potential for increased pollutant loadings to the canal. Normal
design methods would have used treatment ponds to offset these potential impacts. Due
to lack of available land for ponds, altemative treatment methods were proposed for this
project. The District will consider altemative treatment methods if it can be
demonstrated that all other possible altematives have been exhausted. It would not be
possible pohtically to use more school or paric area for treatment ponds. For this project,
CEI showed that the only altematives were to tear down houses for ponds, or use
alternate treatment technologies.
The treatment strategy involved maximizing treatment methods within the project basin
with altemative BMPs, as well as retrofittmg two adjacent watersheds as additional
mitigation. A total of 1.67 acre feet of retention storage was provided in Phase 2 in the
roadside swales and small ponds. This was equivalent to 0.032 inches of retention from
the drainage areas flowing to the retention areas.
A treatment train along Oak Street was designed by using 9 Grated Inlet Skimmer Boxes,
from Suntree Technologies, Inc., in the new inlets to trap debris entering the inlets,
constmcting berms to slow runoff from the ball fields, and installing one baffle box at the
downstream end of the new pipe system along Oak Street. Baffle Boxes are in-line
stormwater treatment devices which tr^ sediment, trash, and debris. They have been
used by Brevard County successfully for the last 9 years. In offsite Basin 4, which only
had one existing baffle box to provide sediment removal, 16 Curb Inlet Skimmer Boxes
were installed in all of the existing inlets to provide nutrient removal by trapping grass
clippings, leaves, and yard debris. Nutrients were a concem in the canals since the
nutrients promote algae blooms, which in tum increase muck build up in the canals. In
offsite drainage Basin 5, there are 3 existing pipes which discharge direcfly to the canals.
Three baffle boxes and 6 curb inlet skimmer boxes were designed to provide sediment
and nutrient treatment for this drainage basin. Brevard County Stormwater Utility will
implement this project and be responsible for all maintenance of the knprovements. The
baffle boxes will be mspected twice a year and cleaned as needed. The inlet traps will be
cleaned twice a year. Brevard County has a vacuum tmck dedicated to cleaning
stormwater BMPs.
Using numerous BMPs used on this project provided a high degree of treatment for the
new pipmg system along Oak Street, and provided treatment for two offsite basins where
little treatment existed. The retrofitting of the offsite areas was, m effect, mitigation for
the new discharges to the canal. See Exhibit 1 for a map ofthe improvements.
Calculations
In Phase 1 of the project, the dry ponds and outfell pipes were modeled hydrauhcally
using the Interconnected Pond Routing program. Since the dry ponds in the Phase 2
project area were too small to provide effective attenuation, the predevelopment and post
development runoff calculations were made using Hydraflow and the rational method.
The only available storm drain pipe for Phase 2 was a 36" pipe in offsite Basin 4. The
new piping along Oak Street was connected to the existing 36" pipe, and the piping
downstream ofthe connection was upgraded to a 42" pipe. The pipes were designed for
a 25 year storm. Basins 1,2, and 3 were a much longer distance from the outfell than
Basin 4. As a result of different times of concentration, the peak flows from Basin 4
passed sooner than Basins 1,2, and 3, givuig only a slight increase in peak discharge,
despite adding 12.25 hectares to the area flowing to the existing outfell.
The potential for increased poUutant loadings in the canal system was a concem of local
residents. These canals had a history of dredging operations every 8-10 years, and the
residents did not want to increase the frequency of costly dredging. The main poUutants
of concem leading to muck deposition in the canals were Total Suspended Solids (TSS),
Total Nitrogen (TN), and Total Phosphoms (TP). Sediment build up at the end of the
pipes was common. Nutrient loadings from grass clippings, leaves, and fertilizers leads
to algae blooms and low dissolved oxygen in the canals, which in tum leads to muck
build up from the eutrophication process. Most ofthe material dredged from residential
canals is typically muck.
To address this concern, a poUutant loadmg analysis of the existing and proposed
stormwater discharges was performed. In the existing conditions, the only stonnwater
treatment for the canal system was a baffle box along Cherry Street for offeite Basin 4 of
24.24 hectares. There were a total of 7 outfaU pipes discharging into the canal system.
In the first phase of this project stormwater treatment was provided for 8.02 hectares of
the school grounds with 3 dry detention ponds. The discharge from these ponds was to
the Indian River, rather than the canal system, so these poUutant loads were not included
in the pollutant load analysis for the canal outfell.
The existing pollutant load to the canal only came from the drainage Basins 4 and 5,
totaling 31.2 hectares. The runoff from Oak Street did not drain to the canal in existing
conditions, only in the post development conditions.
The strategy for the poUutant analysis was to calculate the poUutant toads in the existing
conditions, and then calculate the poUutant loads after the new pipes were added to the
system and offsite areas retrofitted for stormwater treatment. The poUutants used in this
analysis were TSS, TP, and TN.
Each drainage basui was categorized by land use. Areal, annuaL mass loading rates from
"Stormwater Loading Rate Parameters for Central and South Florida", Harper, 1994,
were multiplied by each basin's area to give existing and potential annual pollutant
loadings. See Table 1.
The next step was to calculate the poUutant removal rates for the different BMPs.
Individual BMP removal efficiencies were take from "A Guide for BMP Selection in
Urban Developed Areas", EWRI, 2000. What was challenging with this analysis was the
use of multiple BMPs in series for the treatment tram. Each BMP receives cleaner and
cleaner water as the water moves down the train. At each BMP, the removal efficiency
for each constituent was multiplied by the remainmg percentage of the imtial loading to
give a weighted, cumulative, removal efBciency for each constituent. See Table 2.
These calculated removal efficiencies were then multiplied by the total calculated
poUutant loads to give the reduced pollutant loadings after the BMPs were mstalled. See
Table 3. Table 4 shows that the total loads to the canal were reduced as a resuh ofthe
retrofitting of onsite and offsite basins.
The pollutant loading analysis below demonstrates that as a resuh of the numerous BMPs
proposed, the total pollutant loadhigs entering the canals after project completion will
actually be sigmficantiy reduced from the existing pollutant loadings entering the canals.
The key to overall pollutant reduction is to provide additional treatment in offsite
drarnage basins. This wUl result in a net benefit of reduced poUutants entering the canals
and a reduction of the severe floodmg often seen along Oak Street.
Table 1
Existing Pollutant Loading
Basin
Area
(acres) Land Use
Loading Rate*
(Icg/ac - year)
Potential Pollutant Loading
(kg-year)
Basin
Area
(acres) Land Use TSS
Total
Phosphorus
Total
Nitrogen TSS
Total
Phosphorus
Total
Nitrogen
2A 9.23 Recreational 7.6 0.046 1.07 70.15 0.425 9.876
2B 1.15 Recreationai 7.6 0.046 1.07 8.74 0.053 1.231
20 0.77 Recreational 7.6 0.046 1.07 5.85 0.035 0.824
2D 1.45 Recreational 7.6 0.046 1.07 11.02 0.067 1.552
2E 2.63 Recreational 7.6 0.046 1.07 19.99 0.121 2.814
2F 1.97 Recr^ior^ 7.6 0.046 1.07 14.97 0.091 2.108
2G 0.75 Recreationai 7.6 0.046 1.07 5.70 0.035 0.803
2H 1.29 Recreational 7.6 0.046 1.07 9.80 0.059 1.380
21 0.08 Recreational 7.6 0.046 1.07 0.61 0-004 0.086
2J 0.8 Recreatkxial 7.6 0.046 1.07 6.08 0.037 0.856
2K 0.57 Recreational 7.6 0.046 1.07 4.33 0.026 0.610
2L 0.34 Recreational 7.6 0.046 1.07 2.58 0.016 0.364
3A 2.19 Single FamTy 56.1 0.594 4.68 122.86 1.301 10.249
3B 3.02 Single Family 56.1 0.594 4.68 169.42 1.794 14.134
30 4.02 Low Intend
Commercial 343 0.65 5.18 1378.86 2.613 20.824
Subtotal 30.26 1830.97 6.68 67.71
4" 59.9 Single Fanvly 56.1 0.594 4.68 672.00 24.910 280.332
5A 5.9 Single FanrHly 56.1 0.594 4.68 330.99 3.505 27.612
5B 8.62 Single Fanily 56.1 0.594 4.68 483.58 5.120 40.342
50 2.68 Single Family 56.1 0.594 4.68 150.35 1.592 12.542
Subtotal 77.1 1636.92 35.13 360.83
Totals 107.36 3467.89 41.80 428.54
* From "Stormwater Loading Rate Parameters for Central and South Florida", 1994. Harper
** Basin 4 has an existing baffle box providing treatment.
Basins 4 and 5 are the existing pollutant loadings to the canals.
Table 2
BMP Pollutant Removals
BMP POLLUTANT REMOVAL TABLE*
BMP BMP Removal Efficiency
Type (%)
TSS TP TN
Dry Pond 85 61 91
Swale 80 45 25
Baffle Box 80 30 0
Inlet Trap (grated) 73** 79** 79**
Inlet Trap (curb) 11*** 10***
Swale + Inlet Trap (g) + Baffle Box 98.9 91.9 84.2
Dry Pond + Inlet Trap (g) + Baffle Box 99.2 94.3 98.1
Inlet Trap (c)+ Baffle Box 84 37.7 10
Inlet Trap (g)+ Baffle Box 81.1 85.3 79
Multiple BMP Poilutant Removal Calcuiations
Swale + Inlet Trap (g) + Baffle Box
TSS - 100x0.8 + (100-80)x0.73 + (100-80-14.6)x0.8 = 98.9% Removal
TP - 100x0.45 + (10a45)x.79 + (100-45-43.45) = 91.9% Removai
TN - 100X.25 + (100-25)x.79 = 84.2% Remmak
Dry Pond + Iniet Trap (g) + Baffle Box
TSS - 100x0.85 + (100-85)x0.73 + (100-85-10.95)x0.8 = 99.2% Removal
TP - 100x0.61 + (10a€1)x0.79 + (100-61-30.8)x.3 = 94.3% Removal
TN - IOOx.91 + (100-91)x.79 = 98.1% Removal
Iniet Trap (c) + Baffle Box
TSS - 100-X0.2 + (100-20)x0.8 = 84% Removal
TP - 100x0.11 + (100-11 )x.3= 37.7% Remcwai
TN - IOOx.10 = 10% Removal
Inlet Trap (g) + Baffie Box
TSS - 100x0.73 + (100-73)x0.30 = 81.1% Removai
TP - 100x0.79 + (100-79)x0.3 = 85.3% Removal
TN - 100X.79 = 79% Removai
All removal values are from "Guide For Best Management Praclice
** From Creech Engineers study "Pollutant Removal Testing For a Suntree Teclinologies Grate
Inlet SIdmmer Box", 2001
***From visual observation by Brevard County staff
Tables
Proposed Pollutant Loading
Basin BMP
Type
BMP Removai
Efficiency
From New BMPs
{%)
Pollutant Load
Reduction
From BMPs (kg/year)
Proposed Pollutant
Loading (kgAyear)
TSS TP TN TSS TP TN TSS TP TN
2A swale -^ inlet trap (g) -^ tjaffle t>ox 98.9 91.9 84.2 69.38 0.39 8.32 0.77 0.03 1.56
2B swale+ iriet trap (g) + t>afne box 98.9 91.9 84.2 8.64 0.05 1.04 0.10 0.00 0.19
2C dry pond + inlet trap (g) + baffle box 99.2 94.3 98.1 5.81 0.03 0.81 0.05 0.00 0.02
2D dry pond + iniet trap (g) -<• baffle box 99.2 94.3 9ai 10.93 0.06 1.52 ao9 0.00 0.03
2E dry pond + inlet trap (g) + baffle box 99.2 94.3 98.1 19.83 0.11 2.76 0.16 0.01 0.05
2F swale -•• inlet trap (g) baffle box 98.9 91.9 84.2 14.81 0.08 1.77 0.16 0.01 0.33
2G dry pond ••- inlet trap (g) + t>afne box 99.2 94.3 98.1 5.65 0.03 0.79 0.05 0.00 0.02
2H dry pond + inlet trap (g) + baffle bm 99.2 94.3 98.1 9.73 0.06 1.35 0.08 0.00 0.03
21 smfalte-*- intet trap (g) + baffle t>ox 96.9 91.9 84.2 0.60 0.00 0.07 0.01 0.00 0.01
2J inlet trap (g) + baffle box 81.1 85.3 79 4.93 0.03 0.68 1.15 0-01 0.18
2K inlet traf) (g) -•- t>afne bm 81.1 85.3 79 3.51 0.02 0.48 0.82 0.00 0.13
2L inlet trap (g) + t>afne box 81.1 85.3 79 ZIO 0.01 0J29 0.49 0.00 0.08
3A ipiei trap (g) -^ t>afRe box 81.1 85.3 79 99.64 1.11 8.10 23.22 0-19 2.15
38 inlet trap (g) baffle box 81.1 85.3 79 137.40 1.53 11.17 32.02 0.26 2.97
3C dry pond -•• inlet trap (g) + baffle box 99.2 94.3 98.1 1367.83 2.46 20.43 11.03 0.15 0.40
4 inlet iiap (g) + baffle box 81.1 85.3 79 544.99 21.25 221.46 127.01 3.66 58.87
5A inlet trap (c) + baffle box 84 37 10 278.03 1.30 276 52.96 2.21 24-85
5B ini^ trap (c) + t>afne t>ox 84 37 10 406.21 1.89 4.03 77.37 3.23 36.31
5C inlet trap (c) + b^e box 84 37 10 126.29 0.59 1.25 24.06 1.00 11.29
Total 2305.77 27.24 281.03 197.19 4.34 67.01
Table 4
Net Pollutant Removals
TSS (kg/yr) TP (kg/yr) TN(kg/yr)
Predevelopment 3015.78 35.13 380.83
Postdevelopment 630.97 21.95 289.15
Net Reduction 2384.81 (79%) 13.18(37.52%) 91.68(24.07%)
Summary
The days of solving flooding problems in communities with simple ditch and pipe
solutions have disappeared. Environmental concems now dictate that stormwater
treatment techniques be integrated into these flood relief projects. By addmg water
quality components to water quantity projects, communities can help achieve poUution
remediation goals being estabUshed for NPDES, TMDL, and PLRG programs.
Retrofitting existing stormwater systems to provide water quahty treatment is more
complicated, expensive, and time consuming than traditional stormwater designs for new
development. The scarcity of available land and numerous existmg utilities m older built
out areas will tax an engmeer's imagination to provide ixmovative BMPs m these
locations. An carefiilly planned treatment train was designed consisting of swales, ponds,
berms, baffle boxes, and inlet traps to provide overaU stonnwater poUution reduction.
In order to address stormwater poUution concerns, treatment mitigation was designed in
offsite drarnage basms. The poUutant loadmgs and removals were calculated using a
simple but effective spreadsheet analysis incorporating the latest in BMP efficiency
studies. WhUe complicated stormwater modeling software can be used for pollutant
analysis, this type of modeling is more cost effective on large basin studies than small
basins and individual projects. The poUutant removal calculations showed an annual net
reduction of 79% for TSS, 37% for Total Phosphorus, and 24% for Total Niti-ogen in the
Oak Street basin despite the creation of a new stormdrain system for a landlocked area.
As this project demonstrates, there are typically numerous stakeholders that need to be
brought into the project early in the process and kept m flie process throughout the life of
the project. Many meetii^s were held with city, county, and state officials, homeowners
associations, schools, soccer clubs, churches, and utility companies. All it takes is one
uncooperative stakeholder to set back or kUl a project, as was demonsti-ated with the
church backing out of flie land acquisition process after many verbal indications of
approvaL Using creative parhierships with other entities and agencies allowed the
development ofa unique sfi-ategy to solve flooding at several locations m the project area.
References
ASCE - "Guide For Best Management Practice Selection m Urban Developed Areas"
2001
Gordon England, P.E. "PoUutant Removal Testing For a Suntree Technologies Grate
Inlet Skimmer Box", 2001
Harvey Harper, Ph. D, P.E., "Stormwater Loading Rate Parameters for Central and
South Florida", 1994
POLLUTANT REMOVAL TESTING
FOR A SUNTREE TECHNOLOGIES
GRATE INLET SKIMMER BOX
Prepared for
Suntree Technologies, Inc.
November 2001
CEI Project #21121.00
Prepared By:
11-I'l'li
mmm mQimm, IIMC.
c^¥fly^AT(ioM :. • esvi€Bi!i?-^eERiaD
4450 W. Eau GaUie Blvd., Ste. 232
Melboume, FL 32934
(321)255-5434
TABLE OF CONTENTS
PAGE
Background 1
Methodology 2
Results 2
Table 1 - Sediment Sieve Analysis P
Conclusions 3
APPENDIXA
> Site Photos
APPENDIX B
> Universal Engineering Sciences Grate inlet Skimmer Box
Evaluation Report
Pollutant Removal Testing for a Suntree Technologies
Grate Inlet Skimmer Box
by
Creech Engineers, Inc.
November 2001
With special thanks to Joanie Regan ofthe Cocoa Beach Stormwater Utility
Background;
Over the last several years, a number of BMPs have been developed to provide
stormwater treattnent by trapping poUutants and debris in inlets. Inlet trap BMPs are
quasi source controls, being ine^qiensive, requiring no roadway constniction or utiUty
relocation, and keeping poUutants out of the water bodies, ratha: dian trying to remove
the poUutants from the water once it is contaminated. Suntree Technokigies, of C^
Canaveral, Florida commissioned Creech Engineers, Inc. and Universal Ei^ineering to
perform testing on a Grate Inlet Skimmer Box (GISB) to detenmne its poUutant removal
effectiveness for sediment and grass clq)pings. The testing was perfonned on September
26, 2001. Attached are photogrs^hs from the test and the acconpanying report by
Universal Engineering Sciences.
The GISB is designed to trap sediment, grass, leaves, orgame debris, floating trash, ai^
Itydrocarbons as they enter a grated infet, thereby preventing these poUutants from
entering the stormdrain system where they wouM cause detrimental in^ts on
downstream waterbodies. The GISB is a 3/16" thick fiberglass devfce custom made to fit
most types of grated inlets. The overflow capacity ofthe GISB is designed to be greater
than the curb grate capacity, thereby insuring that there wifl be no toss of hydrauUc
capacity due to the devke being inside the inlet. The bottom ofthe GISB is designed to
be above any pipes entering or leaving the inlet so that flow thiough the inlet is not
blocked.
Water flowing through the grate first encounters a I^drocarbon absorbing ceUulose. This
boom also serves to trap large debris between the boom and the body ofthe GISB. At the
bottom of the trap are a sertos of stainless steel filter screens covering 3.5 inch wide
cutouts in the fiberglass body. These screens trap debris whfle aUowing water to pass
through the bottom of the body and out to the storm drain system. The screens in the
floor and first vertkjal row of the GISB are fine mesh. The second vertfcal row of screens
are medium mesh and the highest row are coarse mesL On the outside ofthe cutouts
the screens are backed by stainless diamond plate to provide sapport to the screens siiKie
heavy loads of debris buiW iq) in the box. Ifthe flow rate through the inlet exceeds the
capacity of the fifter screens there is another row of overflow holes cut out with no
screens. These overflow holes aUow water to pass through the GISB even if it becomes
fiiU of debris. The level of the holes is above the bottom ofthe top tray, enabling the tray
to act as a skimmer to prevent floating ttash fiom escaping through the overflow holes.
About halfway down the box is a diffuser plate to minimize resuspension of trapped
sediment.
Inlet traps such as these are generaUy designed to capture hydrocarbons, sediment, and
floating debris. There is generaUy a large buUd up of grass, leaves, and yard debris in the
GISBs; which represent a source of nutrients, which do not enter the waterbodies. Royal
and England, 1999, determined that leaves and grass leach most of their nuttients into
the water within 24-72 hours after being submerged in water. GISBs are designed to
keep capttired debris in a dry state, off the bottom ofthe inlet, tiius preventing phosphates
and nittBtes from leaching into the stormdrain system, vrfiere much more expensive
BMPs would be required to remove the dissolved nutrients.
Methodology;
A test was designed to simulate a rainfeU event and measure the abUity of a GISB to
remove sediment and grass leaves from a typical grated inlet at 600 South Brevard Ave.,
Cocoa Beach, Florida. Joanie Regan of the Cocoa Beach Stormwater UtUity provided
this location for the test, as weU as a water ttuck to flush the curbs. Universal
Engineering Sciences periformed tiie testing, measurements, and sediment sampUng.
Creech Engineering, Inc. observed the testing.
The City has instaUed a number of tiiese devices and Joanie indicated tiiis location was
typical ofa nonnal instaUatioa The grate, curb, and gutter around and upstteam oftiie
inlet were brushed and washed clean. A new, clean GISB was placed inside tiie inlet. A
water tiuck witii a pmnp discharged reuse water into tiie gutter upstteam ofthe inlet at a
rate of 500 gpm (1.1 cfe). Dry, green St. Augustine grass cUppings from a yard tiiat had
been recently fertUized were slowly fed into tiie gutter and flushed into tiie inlet. It was
observed tiiat tiie cast iron grate ttapped a significant amount of grass around tiie edges of
tiie grate. The grate was removed for aU tests to enable all ofthe grass and sediment to
enter tiie box. After aU ofa measured satap]e of grass had been washed into tiie inlet, tiie
grass was removed from tiie inlet, dried, and weighed. Samples of grass before and after
tiie test were sent to PC&B Laboratories in Oviedo, Ftorida. Laboratory analysis was
performed to detennine the Total Phosphorus and TKN content oftiie grass.
Next, a sediment sample was washed tiirough tiie GISB using tiie same metiiodotogy.
Umversal Engineering ran a sieve size analy^ using ASTM D 422 procedures, before
and after tiie test. The sediment was classified as a poorfy graded gravefy sand. The
sediment was removed fiom the GISB, dried, and weigted.
Results;
During both of tiie tests, aU water leaving tiie GISB passed tiirough tiie filter screens.
The water levels in tiie box onfy rose a few inches, witii no water passing tiirough tiw
overflow holes or coarse screens, even tiiough tiie bottom screens were completety
covered witii grass or sediment. There was a smaU amount of grass and sediment tiiat
passed between tiie box and tiie concrete waUs oftiie inlet because oftiie uneven edges of
the inlet. This situation is feirly common in most inlets due to loose tolerances in
constmction techniques.
In the grass test, 6.58 lbs. of grass were washed into tiie inlet and 5.22 lbs. were
capttired, resulting in 1.36 lbs. of grass passing tiirough the GISB. This represents a
removal efBciency of 79.3%. The pretest grass sample had a Total Phosphorus content of
950 mg/kg and a TKN content of 510 mg/kg. The grass sample removed from the GISB
had a Total Phosphoms content of2,270 mg/kg and TKN content of905 mg/kg.
The sediment test was a Uttle more complex. The initial results ^owed that ofthe 57.87
lbs. of sediment inttoduced to the GISB, 42.41 Ibs. Avere captured, giving a total mass
removal efBciency of 73.3%. Umversal Engineering indicates that the Pretest sanpto had
10.7 % gravel, 88.0% sand, and 1.4% clay. The Post test sampfe had 25.9% gravel,
14.7% sand, and 1.7% clay. Gravel is considered to be parttoles No.4 and larger. SUt
and clay is defined as particles passing the No. 200 sieve.
Table 1
Sediment Sieve Anafysis
Sieve Size 3/8" No.4 No.10 No.40 No. 60 No. 100 No. 200
PreTest
% Passing
94.3 89.3 81.8 64.8 50.3 25.5 1.4
Post Test
% Passmg
88.8 74.1 62.6 44.2 31.8 14.7 1.7
Difference 5.5 15.2 19.2 20.6 18.5 10.8 -0.3
Conclusions;
At tiie flow rate tested, tbe GISB removed 79.3% ofthe grass clqjpings washed into it.
The abUity of tte GISB to remove grass during large flows yvbea water passes through
tiie bypass holes was not tested. In Florida, 90% oftiie storms are low rainfeU events of
1" or less, resulting in low flows simUar to tiie test conditions. This makes tiie GISB a
very effective BMP for Low flow events. It is unknown how effectively the GISB works
in large storm events.
By keeping grass and other trapped organic debris in a dry state, the nuttients in the
debris do not leach out and become dissohred nitrates ami phosphates. The GISB is a
very effective BMP for preventing nuttients from orgame debris from entering
waterbodies. The significant increase in nutrient concentt^on after the test is probably
attributed to the use of wastewater reuse water during tiie test. The grass matted several
inches thick m the bottom of tiie box. This tiiick layer could have acted as a filter to
remove nutrients from the water source.
At the flow rate of 1.1 cfe, tiie GISB had a sediment removal efBciency of 73.3%. As
would be expected, most of the tr^ped sediment was gravel and sand, witii Uttle fine
material coUected. The GISB has sediment removal capabflities rivaUng those found in
many sttucttiral BMPs, at a fi:action of the cost, and witiiout disraptive constiuction.
UNIVERSAL
ENGINEERING SCIENCES
Ca«ulbnts In: Gecieciviical Engneering • Efwinx^^
Constmciion Maierials tesling • Thceshold Inspeclion
620 Brevard Avenue • Rockledge, Florida 32955
(321)638-0808 Fax (321) 638-0978 . '
November 2, 2001
Mr. Gordon England, P.E. ^
Creech Engineers, Inc.
4450 West Eau Gallie Boulevard
Melbourne, Florida 32934
Reference: Grate Inlet Skimmer Box Evaluation
Northwest Comer of South Brevard Avenue and South 8** Street
Cocoa Beach, Brevard County, Florida
Universal Project No. 33186-002-01
Universal Report No. 51479
Dear Mr. England:
Universal Engineering Sciences, Inc. (Universal) has completed an evaluation of a Grate Inlet
Skimmer Box (GISB) in accordance with Universal Proposal No. P01-0781. The evaluation was
conducted to document the pollutant removal effectiveness at the above-referenced site. A
Location Map, Site Map and Site Photographs are presented as Attachments 1. 2 and 3,
respectively.
Sediment Testing
Universal supplied the sediment sample for the GISB evaluation. The sediment sample
consisted of fine sands, coarse grain sands with crushed shells, and gravel. A gradation
analysis of the sediment sample (S-1) was performed, prior to GISB perfomiance testing. The
percentages of soil grains, by weight, retained on each sieve were measured and a grain size
distribution curve generated, to detennine the textural nature of the sample and provide a
control (baseline) prior to fieldwork.
A sediment sample of known weight (57.87 Ibs.) was placed on the pavement upstream of the
GISB and washed into the GISB with a portable water source simulating a storm event. The
captured sediment was then removed firom the GISB. dried and weighed. The captured
sediment weighed 42.41 Ibs. resulting in a loss of 15.46 Ibs. from Uie GISB testing. A gradation
analysis of the captured sediment sample (S-2) was performed.
Universal completed particle size analyses on the two representative sediment samples (S-1
and S-2). The samples were tested according to the procedures for mechanical sieving of
ASTM D 422 (Standard Method for Particle Size Analysis of Soils). In part, ASTM D 422
requires passing each specimen over a standard set of nested sieves (% inch. No. 4. No. 10.
No. 40, No. 60, No. 100, No. 200). The percentage of the soil grains retained on each sieve size
are detemiined to provide the grain size distribution of the sample. The distribution determines
the textural nature of the soil sample and aids in evaluating its engineering characteristics.
Mr. Gordon England
November 2, 2001
Page 2
Project No. 33186-002-01
Report No. 51479
S-1 consisted of 10.7 percent gravel (grain size larger than 4.75 mm), 88.0 percent sand (grain
size between 0.075 mm and 4.75 mm), and 1.4 percent fines (grain size less than 0.075 mm).
S-2 consisted of 25.9 percent gravel, 72.4 percent sand, and 1.7 percent fines. The grain size
distribution curves are presented as Attachment 4. According to the Unified Soil Classification
System (USCS), S-1 and S-2 were classified as pooriy-graded gravely sand [SP]. Based on the
gradation analysis, the major portion of the lost sediment was the fine sand component.
Grass Clippings Test
The grass clippings were supplied by Suntree Technologies. A grab sample of grass (G-1) was
collected and submitted for laboratory analysis to detennine the TKN (EPA Method 351.2) and
Total Phosphoms (EPA Method 365.3) content A grass sample of known weight (6.58 Ibs.) was
placed on the pavement upstream of the GISB. The grass clippings were washed Into the GISB
in the same manner as the sediment sample. The capUjred grass clippings were then removed
from the GISB. dried and weighed. The captured grass clippings weighed 5.22 Ibs. resulting in a
loss of 1.36 Ibs. A second grab sample (G-2) was collected from the captured grass clippings
and submitted for laboratory analysis to detemnine the removal efficiency for TKN and Total
Phosphoms.
The samples were shipped to PC&B Laboratories, Inc. in Oviedo, Rorida. Laboratory analysis
documented 950 milligrams per Kilogram (mg/Kg) of Total Phosphoms and 510 mg/Kg of TKN
?.^K?^''' analysis documented 2,270 mg/Kg of Total Phosphorus and 905 mg/Kg of
TKN for G-2. Laboratory Analytical Results and Chain-of-Custody Documentation are presented
as Attachment 5.
Universal appreciates the opportunity to provide environmental services as part of your project
team. Should you have any questions, please do not hesitate to contact the undersigned at (321)
638-0808.
Respectfully submitted.
Universal Engineering Sciences, Inc.
James E. Adams^—
Staff Scientist II
(2) Addressee
Attachments
Robert Alan Speed
Regional Manager
Rockledge Branch Office
Attachment 1
Attachment 2
Attachment 3
Attachment 4
Attachment 5
Site Location Map
Site Map
Site Photographs *
Soil Gradation Curves
Laboratory Analytical Results and Chain-of-Custody Documentation
\\uesrock\data\reports\envrpts\env2001\51479 gisb evaluation reportdoc
ATTACHMENT 1
SITE LOCATION MAP
• % .r-i- ;• ,
Mil"
Grate Inlet Skimmer Box Evaluation
South Brevard Boulevard
Cocoa Beach, Brevard County, Rorida
UNIVERSAL SITE LOCATION MAP
J ADAMS
SCQX^ "
BATE; CMECKEOSY:
JAOAIMS 103001
AS SHOWN PHuJbUf ND^ ~ HtMOHINO:
51479
PA6ENIJ:
ATTACHMENT 1
ATTACHMENT 2
SITE MAP
RESIDENTIAL
CONDOMINIUMS
CONDOMINIUM DRIVEWAY
t LANDSCAPED ^
MEDIUM J
RESIDENTIAL
CONDOMINIUMS
I
UJ
9
w
UJ 9
to
Ul
Z UJ
i
Q
CH $ Ui cr:
CQ
X H
o
CO
RESIDENTIAL
CONCRETE
DRAINAGE S\NALE
SOUTH 8™ STREET
RESIDENTIAL
Grate Inlet Skimmer Box Evaluation (/M
South Brevard Boulevard ^
Cocoa Beach, Brevard County, Florida ^
UNIVERSAL
ENG»EER»IG SCIENCES
SITE MAP UNIVERSAL
ENG»EER»IG SCIENCES J. AOAMS DKTE:
10/30/01
CHECXBIBY:
J. ADAMS
MTE
10/30/01 SCALE;
^.—fcns-
PROJECTNO:
331fl6^X)?-ni
REPORT NO:
51479
PAGE NO:
_-ArrACHMENT2
ATTACHMENTS
SITE PHOTOGRAPHS
Grate Inlet at 600 South Brevard Avenue, Cocoa
Beach
Grate Inlet Skimmer Box Features
Rorida Type C Inlet
Storm Boom
Zip Tie
Skimmer Tray
Deflection Shield
Flange is reinforced
with knitted 1808 ±45°
biaxial fiberglass
ttEECH m^i I'f
PoUutant Removal Testing for a
Sunttee Technotogies Grate Inlet
Skimmer Box
SITE PHOTOGRAPHS
Sediment Entering GISB
Sedhnent Trapped in GISB
cm
'I^'l\i37 •ERS. !MC.
E?\?G8I^JEERED
PoUutant Removal Testing for a
Suntree Technologies Grate Inlet
Skimmer Box
SITE PHOTOGRAPHS
GISB Inserted into Inlet
WiXSHITi'g
Grass Testing
PoUutant Removal Testing for a
Simttee Technologies Grate Inlet
Skimmer Box
SITE PHOTOGRAPHS
• 1 '^.ra^
Grass CUppings Entering GISB
SIP
Sediment Testing
tHEECH EiiWIERS.. IMC. Pollutant Removal Testing for a
Suntree Technologies Grate Met
Skimmer Box
SITE PHOTOGRAPHS
Photo No. 1: (Pre-Test) Installation of new GISB
Photo No. 2: Start of the grass clippings test
Grate Inlet Skimmer Box Evaluation
NWC of South Brevard Avenue and South 8'" Street
Cocoa Beach, Brevard County. Florida
SITE PHOTOGR/\PHS
N/A
ISCHTET
N/A
tWME: loraowi
wmiUiHU
33186-024)1
N/A
61479
lorao/oi
PAGE1
Photo No. 3: Stonm simulation for the grass dip test
Photo No. 4: Completion of grass clippings test. GISB removed for
cleaning.
sm Grate Inlet Skimmer Box Evaluation
NWC of South Brevard Avenue and South B'" Street
Cocoa Beach, Brevard County, Ftorida
SfTE PHOTOGRAPHS
N/A DAIE:
N/A
lorsiVDi
3CCKa>BY:
33186-02-01
N/A
51479
10/30/01
PAGE 2
Photo No. 5: Start of sediment test.
Photo No. 6: Sediment test in progress.
Grate Intot Skimmer Box Evaluation
NWC of South Brevard Avenue and South 8*" Street
Cocoa Beach. Brevard County, Florida
SITE PHOTOGRAPHS
N/A
DATE:
N/A
1IV3D/01
3CCKEDBY:
WLUkUINU
3318602-01
N/A
JAI6:
^TORTTBr
61479
10/30/D1
PAGE 3
Photo No. 7: Completion of sediment test,
Photo No. 8: Stomiwater catch basin after testing
Grate Intet Skimmer Box Evaluation
NWC of South Brevard Avenue and South 8'" Street
SITE PHOTOGR/\PHS
N/A 10/30/01 31ECKE0BY:
N/A JftTE:
10/30/01
N/A 33186-02-01 TPtmm •—
51479
^IsfcNU ~"—'—
PAGE 4
ATTACHMENT 4
SOIL GRADATION CURVES
U.S. SIEVE OPENING IN INCHES
6
1
U.S. SIEVE NUMBERS
14*
TT
HYDROMETER
GRAIN SIZE IN MIUIMETERS 0.01 0.001
1 COBBLES GRAVEL 1 SAND SILT OR CLAY 1 COBBLES coarse | fme 1 coarse | medium | tme SILT OR CLAY
Specimen Identification Classification MC% LL PL PI Cc Cu
SI 0.79 3.7
SEDIMENT 1
Spedmen Identification D100 D60 D30 DIO %Gravel %Sand %Silt %Clay
• SI 12.50 0.36 0.164 0.0961 10.7 88.0 1.4
3/4" 3/8" NO.4 NO. 10 NO.40 NO. 60 NO. 100 NO. 200
94.3 89.3 81.8 64.8 50.3 25.5 1.4
Client: CREECH ENGINEERING
4450 W. EAU GALUE BOULEVARD
MELBOURNE FLORIDA 32934
Project: GRATE INLET SKIMMER
BOX EVALUATION
BREVARD COUNTY, FLORIDA
Client No:
Report No:
Date:
33186-002-01
51479
10/9/01
SOIL GRADATION CURVES
Universal Engineering Sciences. Inc.
100
95
90
85
80
75
70
65
60
55
50
U.S. SIEVE OPENING IN INCHES
6
rTTi * 3 2 1.5 ^ a/4 M ' 4
U.S. SIEVE hAJMBERS
14*
rr
« e'" 14*20 » 40 » TO'^I*
HYDROMETER
200
rr
R
45
B
Y 40
IW35
G^
" 25
20
15
10
5
0
10
GRAIN SIZE IN MILLIMETERS
SAND
0.1 0.01 0.001
COBBLES GRAVEL
Specimen Identification Classification LL PL PI Cc Cu 1
• S2 0.30 13.7 1
SEDIMENT 2
Specimen Identification D100 D60 D30 DIO %Gra\ rel % Sand %Sit I >Clay 1
• S2 12.50 1.61 0.237 0.1169 25.9 72.4 1.7 1
3/4" 3/8" NO.4 NO. 10 NO.40 NO. 60 NO. 100 NO. 200
88.0 74.1 62.6 44.2 31.8 14.7 1.7
Client CREECH ENGINEERING
4450 W. EAU GALUE BOULEVARD
MELBOURNE FLORIDA 32934
Project GRATE INLET SKIMMER
BOX EVALUATION
BREVARD COUNTY, FLORIDA
Client No:
Report No:
Date:
33186-002-01
51479
10/9/01
SOiL GRADATION CURVES
Unhrersal Enalneerina Sciences. Inr
ATTACHMENTS
LABORATORY ANALYTICAL RESULTS AND
CHAIN-OF-CUSTODY DOCUMENTATION
PC&B Environmental Laboratories, Inc.
210 Park Road, Oviedo, Florida 32765
Phone: 407-359-7194 Fax: 407-359-7197
Client: Universal Engineering Sciences
820 Brevard Avenue
Rockledge. FL 32955-
Contact: James Adams
Phone: (321) 638-0808
Laboratory Reference Number: 201090199
Project Name : Inlet Skimmer Box Evaluation
Project Number:
Laboratory ID Matrix Client ID
201090199-1 Solid G-1
Chain ofCustody: 24025
Status Date/Time Sampled
RUN 09/26/2001 14:20
Number
1
Parameter Description
EPA 6010
EPA 9200/351.2
Phosphorus by IC/VP
Total Nitrogen
PC&B Environmental Laboratories, Inc.
210 Park Road
Oviedo, FL 32765-8801
407-359-7194 - (FAX) 407-359-7197
Case Narrative
James Adams
Universal Engineering Sciences
820 Brevand Avenue
Rockledge, FL 32955-
CASE NARRATIVE for Wori< Order: 201090199
Project Number:
Project Name: Inlet Skimmer Box Evaluation
This Case Narrative is a summary of events and/or problems encountered with this Work Ordar
Analysis for TKN was perfonned by Environmental Science Corporation (E87487)
Definilion of Fbos
DL = No surrogate result due to dOubon or matrix interfeience ~ ~
J = Estimated Value, value not accurate.
L = Ofr-scaie liigh. Actual vaiue is grealer ttian value given
Q = Sample analyzed beyond the accepted hohfing time
T = Value reported is less than the laboratory method detection HmR.
V = Analyte was bo«h detected in the method blank and sample
PC4B Environmental Laboratories Inc Rannrt ..t i. • _
210 Paric Road ™nes, inc. Reportof Analysis CL'^NT NAME: Universal Engineering Sciences
Oviedo. FL 32765-8801 PROJECT NAME: Inlet Skimmer Box Evaluation
PHONE: 407-359-7194 PROJECT NUMBER:
Lab Reference Number 201090199-1 DATE RECEIVFO nq/?R/?nni
CHent Sample ID Q_.,
Datemme Sampled 09/26C001
Sample Matrix (as Received^
EPA 6010 Phosphorus, Total mg/kg Iso ' • .
EPA 9200/351.2 Total Nitrogen mg/kg 510
U ^Undetected. The value preceedlng the Vte the RLfc. the ^ P>>-..|ts reported on a W..W».MK...
rutKUompUAPP#900134G - FDOH Cert.I.cat.on # E83239 ''
Reviewed by: VjL-TY^
Quality Control Report for Spike Analysis
INORGANICS
e^iir. Lower Upper
. *P"* Sample Spike Percent Control Control
ass^^ ^^^..^ .S^'^'^'^"^^'^^-^^^^-^
^6 0 Park R35CI, Oviedo, FL 32765
7-359-7194 (FAX) 407-359-7197 Chain of Custodv| Work Order
Date
01 "^9
Page of
WHITE: Ptetmet mim vmi • nu..
?.rai:^7iy'°^^giT'_JgjTain oftustodv Work Order: ak)li6^>i
WHITE noiwtFM* vSTrwEiTC
PC&B Environmental Laboratories Inc
'210 Pai* Road
Oviedo, FL 32765-8801
PHONE: 407-359-7194
Reportof Analysis
Lab Reference Number
Client Sample ID
Date/Time Sampled
Sample Matrix fas Received)
201100168-1
G-2
10/10/2001 0:00:
Solkt
CLIENT NAME: Universal Engineering Sciences
PROJECTNAME:
PROJECT NUMBER:
DATE RECEIVED: 10/180001
EPA 6010
EPA 9200/351.2
Phosphorus, Total
Total Nitrogen
mg/kg
mg/kg
2270
905
U = Undetected. The value preceedinc '^^ Y.^.}^^ ^^^""^ ^ported on a W^t w^ir^hf basis
hutK CompQAPP # 900134G - FDOH Certification # E83239
Reviewed by;
PC&B Environmental Laboratories, Inc.
210 Park Road, Oviedo. Florida 32765
Phone: 407-359-7194 Fax: 407-359-7197
Client: Universal Engineering Sdences
820 Brevard Avenue
Rockledge, FL 32955-
Laboratory Reference Number: 201100168
Project Name:
Project Number:
Latwratory ID Matrix Client ID
Contact: Bob Speed
Phone: (321) 638-0808
Chain of Custody: 20344
Status Date/Ttme Sampled
201100168-1 Solid G-2 RUN 10/10/2001
Number Parameter Descriptfon
EPA 6010
EPA 9200/351.2
Phosphorus by ICAP
Total Nitrogen
Quality Control Report for Spike Analysis
INORGANICS
Lower Upper
SpBte Sample Spike Percent Control Control
f^y^, Rest* ResuK Recovery Limit Limit
IMhod: B>A eOlOA QC Balch: 2aj110RC107 gmge»^^ IMe f^: lOnSQOOl An.1: l6na/^1 Analyst GG
Phosphorus. Total 20.0 mgfltg 178.0 199.0 105 70 120
SHE EVALUATION OF SUNTREE TECHNOLOGIES, INC.
GRATE INLET SKIMMER BOXES
FOR DEBRIS, SEDIMENT, AND OIL & GREASE
REMOVAL
Reedy Creelc ]mpn>Yemeiit District
Planning & Engineering Department
Eddie Snell, Compliance Specialist
StmnwatBT is now recogmzed as the leading source of pdhitioo to our lanainii^ natural
wata- bodies in Ae United States. Devdkipoient and udxmizirtion have lonoved mo^ of
tiie natural filtratioo and sedimoit tr^jping systems provided by tiie mvircMimOTt Cunent
development must address tiiis need through die implemeoitation of stonnwater
treatments systraas in tin fHcyect deagn. Most of tiiese systons pofinm reasonaUy weU,
if ptapesfy designed, constiiKtBd, and mamtaiaed.
Retrofit of oldo" uiban areas laddng tiiese modem stCHmwater systems is a continually
expensive challaige. The Downtown Disney complex, fonnerly tiie Lake Buena Vista
Shopping Village has sevoal drainage basins witii 1970's stunnwito systraos. These
older systems disdunge directfy mto tiie adjacent drarnage canal vntii no pollutant
treatment OVCT time tiie accumulation of sediments, nutrients, intraisive development,
and recreational/entertainment pressures are c(»itributing to water quality d^radation.
Whenevo- new devdopment or redevelqnnent occurs, tiie stormwata- system is brought
to currrait code/permit requirements. In flte interim, several areas are in need for r^id,
effective, and economical improvonent in tiie quality of its stonnwater discharge.
Suntree Tedinologies InccHpcxalBd, located in Cape Canavoal, FL, manu&ctures
stonnwater grate inlet skimmer boxes. They are made of a high quality fiberglass tame,
witii stainless steel filta- scre^ backed by heavy-duty aluminum grating. Each unit is
custom made to accommodate various inlet sizes. A hydrocarbon absorption boom is
attached to tiie top of tiie skimmer box for petroleum, oil, and grease removal.
These devices fit below tiie grate and catch sediment, debris, and petroleums, oils &
greases. Clean-out, maintenance, and performance reporting is provided by Suntree on a
scheduled basis.
Picture of Grate Inlet Skimmer Box
The Reedy Creek Improvement District (RCID) selected six (6) test sites in tiie Lake
Buena Vista area to evaluate tiie performance of tiiese units. One unit was placed in a
cuii) inlet alcmg Hotel Plaza Boulevard to tr^ landscape leaf litter, sediment, and oil &
grease fi-om a high use roadway. Three (3) units were placed in tiie backstage service area
of die Rain Forest Cafe. Two (2) units were placed in the backstage service area of tiie
McDonald's restaurant and Legos merdiandise shop.
After several field meetings, during which Suntree took extensive measurements, photos,
and otiier documentation of each stormwater drain, tiie Grate Inlet Skimmer Boxes were
manufactured and delivered for installatim. All units were installed witiiout mishap
approximately two weeks before tiie 1999 Christmas holiday season. The target time
period for particle catchment was one montii. Mr. Hemy and Tom Happel, Suntree
Technologies, visited each site several times during tiie montii to ensure tiiat debris would
not fill tiie units too soon.
On January 25,2000, Suntree serviced flie six units. At each site, the material captured in
tiie skimmer boxes was removed, measured, weighed, visually identified, photographed,
and recorded. Some units were sligjitiy field modified for optimum performance. All
units poformed as expected removii^ on average, 20 poimds of ddxis from eadi of
the sbc dtes. The c(»npositi(n of debris varied ccndderably.
The Hotd Plaza (roadw^) site was 90% leaf litter and 10% sediment ITie Rain Fwest
Cafe sites ran in opposition as you got close to tiie lake. First inlet was about 50% leaf
litter and cigarette butts and 50% sediment The middle inlet was 60 %sedim«it and 30
% leaf litter (10% miscellaneous). The inlet closest to tiie lake was 95% sediment and 5%
leaf litter. The two sites at tiie McDonalds/Legos area were similar to each otiier. The
site closest to tiie lake was 95% sediment and 5% leaf litter. The site closest to tiie
entrance gate was 98% litter sediment and 2% leaf litier.
This composition is indicative of tiie human activities and drainage flow pattems of tiiat
site. Backstage areas in tiie Walt Disn^ Worid Resot receive an artifidal rain event
each night during cleaning operations. This washes a continual flow over tiie impervious
site, washing all materials into tiie stonnwater system.
Municipalities in Brevard, Volusia and Dade counties have successfiilfy used inlet
skimmers in Florida. RCID partnraied witii Walt Disney Imagineering (WDI) Research
and Development to coonlinate some basic chemical sampling for pollutant removal
efBciency detennination. Mr. Craig Duxbury, WDI, provided technical support and
guidance for tiiis. An ingenious^ ample device was fabricated by Suntree to allow
sampling of tiie First Flush of water going into tiie units and ultimately coming out of tiie
skimmer boxes.
Collected samples were processed and analyzed by tiie RCID Environmental Services
Laboratory. Analysis parameter were:
Ammonia, Chemical Oxygen Demand, Fecal Colifomi (MPN), Nitrite and Nitrate, Total
Kjeldahl Nitrogen, Oil and Grease, Total Phosphate, Suspended Solids, and Metals.
Analysis results are presented in tiie following table:
Pollutant
ANALYSIS LOCATION LAB NO. VALUE UNITS SAM-DATE Chanoe
Ammonia, Salicylate RF-IN 1646 0.38 mg/1 09-FebOO 0.14
Ammonia, Salicylate RFOUT 1646 0.23 mg/1 09-Feb-OO
Ammonia, Salicylate RF-OUT-I 1646 0.25 mg/1 09-Feb-OO
Chemical Oxygen Demand RF-IN 1646 2670 mg/1 09-Feb-OO 1036
Chemical Oxygen Demand RF-OUT 1646 1780 mg/1 09-Feb-OO
Chemical Oxygen Demand RF-OUT-I 1646 1490 mg/1 09-Feb-OO
Coliform, Fecal MPN RF-IN 1646 1600 #100 ml 09-Feb^ •93400
Conform, Fecal MPN RFOUT 1646 160,000 #100 ml 09-Feb-OO
Conform, Fecal MPN RF-OUT-I 1646 30,000 #100 ml 09-Feb-OO
Nitrate and Nitrite RF-IN 1646 0.06 mg/1 09-FebOO 0.035
Nitrate and Nitrite RF-OUT 1646 0.04 IT^ 09-Feb-OO
Nitrate and Nitrite RF-OUT-1 1646 0.01 mg/1 09-Feb-OO
Nitrogen, Total l^eldahl RF-IN 1646 24.3 mg/1 09-Feb^ 13.55
Nitrogen, Total Kjeldahl RF-OUT 1646 10.4 mg/1 09-Feb^)0
Nitrogen, Total Kjeldahl RF-OUT-l 1646 11.1 mg/1 09-Feb^
Oil and Orease RF-IN 1646 526 mg/1 09-Fel)-00 283
%
Chanae
37%
Pollutant removal efficiencies averaged about 50% for all parameters tested. The minimal removal was
3?/o for Ammonia and the maximum ranoval was 74% for Suqjended Solids.
Colifomi bacteria were not effectively removed by Ae skimmer boxes, althot^ they are not designed to
provide water disinfection. Oil and Grease are a food source for bacteria and reduction of this pollutant
should provide some effect on bacterial numbers.
Pollutant Removal Efficiency
80%
70%
60%
c
0
50% 0 '
o
5 40%
m
^ 30%
20%
10%
0%
% Change
Parameter
I Ammonia,
Salicylate
I Chemical Oxygen
Demand
• NRrale and Nitrite
• Nitrogen, Total
Kjeldahl
• Oil and Grease
• Phos|4iate, Total
• Solids, Suspender