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Home My WebLink AboutCT 05-07; BRESSI RANCH LOT 40; STORM WATER MANAGEMENT PLAN; 2006-01-16I I I I I I I I I I I I I I- I I- I- I I Prepared By Partners Planning and Engineering STORM WATER MANAGEMENT PLAN FOR BRESSI RANCH LOT 40 City of Carlsbad DWG No. 935-3A PROJECT No. CT-05-07 Prepared By Partners Planning and Engineering 15938 Bernardo Center Drive San Diego, CA 92127 For St Croix Capital 4350 Executive Drive, suite 301 San Diego, CA 92121 January 16, 2006 RECIIlVED JAN 192006 ENGINEERING - DEPARTMENT \ \Server\c-drive\dwg\577\577 -swmp_doc 1/16/2006 I I TABLE OF CONTENTS I INTRODUCTION 1. Project Desc)·iption ...............................................................•............................ I 1.1. Hydrologic Unit Contribution ...............................................................•..• I I I I I I I I I I I I I I I 1.2. Beneficial Use ............................................................................................. . 1.2.1. Inland Surf~lce Waters ................................................................. . 1.2.2. Groundwater ................................................................................. . 2. CHARACTERIZATION OF PROJECT RUNOFF ..................................... . 2.1. Expected Pollutants from the Project Area ........................................... .. 2.2. Pollutants of Concern ................................................................................ . 2.3. Conditions of Concern .............................................................................. . 3. MITIGATION MEASURES TO PROTECT WATER QUALITY 3.1. Construction BMPs ................................................................................... . 3.2. Post-construction BMPs ........................................................................... . 3.2.1. Site Design BMPs ............................................................................ . 3.2.2. Source Control BMPs .................................................................... . 3.2.3. Treatment Control ......................................................................... . 3.2.3.1. Fossil Filter TM Storm Water Filtration System .............. .. 3.2.3.2. Biofilters (Vegetated Swales) ..•...........•..•••.•..•...•...........•.. 3.2.4. Target Pollutants and Proposed BMPs ....................................... .. 4. OPERA TION AND MAINTENANCE PROGRAM .................................... . 4.1. Source Control BMPs ............................................................................... . 4.1.1 Hazardous Material Storage ......................................................... . 4.1.2 Trash Storage .................................................................................. . 4.1.3 Efficient Irrigation S)'stem ........................................................... .. 4.1.4 Inlet I Catch Basin Tiles ................................................................ .. 4.1.5 Good Housekeeping ..................................................................... , ... . 4.2 Treatment Control BMPs ........................................................................ . 4.2.1 Fossil Filter 1'M Storm Water Filtration System ..............•...•........•.. . 4.2.2 Biofilters (Vegetated SV\'ales) ....................................................... .. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\S77\S77-swmp.doc 1/16/2006 I I I I I· I I I I I I I I I I I I I I 5.0 Fiscal Resources ....................................... ······ ............................................. . 6.0 Conclusions ................................................................................................. . ATTACHMENTS A. Vicinity Map B. Project Map C. Calculations D. Appendix E. Operation and Maintenance Plan Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577-swmp.doc 1/16/2006 I I I I I I I I I I I I I I I I I I I INTRODUCTION The Storm Water Management Plan (SWMP) requirement is required under the City of Carlsbad's Storm Water Management and Discharge Control Ordinance. The purpose of this SWMP is to address the water quality impacts from the proposed development of Bressi Ranch Lot 40 in the City of Carlsbad. Best Management Practices (BMPs) will be utilized to provide a long-term solution to water quality. This SWMP is also intended to ensure the effectiveness of the BMPs through proper maintenance that is based on long-term fiscal planning. 1. PROJECT DESCRIPTION The proposed development, approximately 390,864 ft2, includes fifteen (15) office buildings with 475associated parking, landscaping and hardscape. The project site is located east of Interstate 5 and south of Palomar Airport Road. Access to the site occurs off of East Loker Avenue. See Attachment 'A' for Vicinity Map. 1.1 Hydrologic Unit Contribution Bressi Ranch Lot 40 is located in the Agua Hedionda Hydrologic Subarea of the San Diego County Coastal Streams Hydrologic Area (HSA 904.31) of the Carlsbad Hydrologic Unit. The project site is currently vacant consisting of a mass graded pad. Runoff developed on site currently sheet flows from the northeast to the southwest to the existing desiltation basin. The runoff is then conveyed via the existing public storm drain system to Agua Hedionda Creek. The proposed development will not significantly affect the cun'ent drainage pattern. The existing condition generates 18.5 cfs for the 100-year storm. The proposed developed site generates 28.2 cfs for the 1 OO-year storm (w/o detention). The site design includes on-site detention facilities, to be used as sediment basin during construction, designed to limit the post-development -flows to pre-existing conditions. In addition, the existing condition generates 11.7 cfs and 8.2 cfs during the lO-year and 2-year storms respectively. The proposed developed site generates 17.8 cfs and 12.6 cfs during the 10-year and 2-year storms respectively. See Section 2 for a basin break down and Attachment C for calculations. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 I I I I I I I I I I I I I I I I I I I 1.2 Beneficial Uses The beneficial uses for the hydrologic unit are included in Tables 1.1 and 1.2. These tables have been extracted from the Water Quality Control Plan for the San Diego Basin. MUN -Municipal and Domestic Supply: Includes uses of water for community, military, or individual water supply systems including, but not limited to, drinking water supply. AGR -Agricultural Supply: Includes uses of water for farming, h0l1iculture, or ranching including, but not limited to, irrigation, stock watering, or support of vegetation for range graz1l1g. IND -Industrial Service Supply: Includes uses of water for industrial activities that do not depend primarily on water quality including, but not limited to mining, cooling Water supply, hydraulic conveyance, gravel washing, fire protection, or oil well re-pressurization. RECl-Contact Recreation: Includes uses of water for recreational activities involving body contact with water, where ingestion of water is reasonably possible. These uses include, but are not limited to, swimming, wading, water-skiing, skin and SCUBA diving, surfing, white water activities, fishing, or use of natural hot springs. REC2 -Non-Contact Recreation: Includes the uses of water for recreation involving proximity to water, but not normally involving body contact with water, where ingestion of water is reasonably possible. These uses include, but are not limited to, picnicking, sunbathing, hiking, camping, boating, tide pool and marine life study, hunting, sightseeing, or aesthetic enjoyment in conjunction with the above activities. BIOL -Preservation of Biological Habitats of Special Significance: Designated areas or habitats such as established refuges, parks, sanctuaries, ecological reserves, or Areas of Special Biological Significance (ASBS), where the preservation or enhancement of natural resources requires special protection. EST -Estuarine Habitat: Estuarine ecosystems including, but not limited to, preservation or enhancement of estuarine habitats, vegetation, fish, shellfish, or wildlife (e.g., estuarine mammals, waterfowl, shorebirds). WARM -Warm Freshwater Habitat: Includes uses of water that support warm water ecosystems including, but not limited to, preservation or enhancement of aquatic habitats, vegetation, fish or wildlife, including invertebrates. COLD -Cold Freshwater Habitat: Includes uses of water that support cold water ecosystems including, but not limited to, preservation or enhancement of aqu~tic habitats, vegetation, fish or wildlife, including invertebrates. WILD -Wildlife Habitat: Includes uses of water that support terrestrial ecosystems including, but not limited to, preservation and enhancement of terrestrial habitats, vegetation, wildlife, (e.g., mammals. birds, reptiles, amphibians, invertebrates), or wildlife water and food sources. RARE -Rare, Threatened, or Endangered Species: Includes uses of water that support habitats necessary, at least in part, for the survival and successful maintenance ofplallt and animal species established under state or federal law as rare, threatened, or endangered. MAR -Marine Habitat: Marine ecosystems including, but not limited to. 'preservation or enhancement of marine habitats, vegetation such as kelp, fish, shellfish, or wildHfe (e.g., marine mammals, shorebirds). Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp. doc . 1/16/2006 I I I I I I I I I I I I I I I I I I I MIGR -Migration of Aquatic Organisms: Habitats necessary for migration, acclimatization between fresh and salt water, or other temporary activities by aquatic organisms, such as anadromous fish. SPWN -Spawning, Reproduction, and/or Early Development: High quality habitats suitable for reproduction and early development offish. This use is applicable only for the protection of anadromous fish. 1.2.1 . Inhmd Surface Waters Coastal waters have the following beneficial uses as shown on table 1.1 Table 1.1 Beneficial Uses of Coastal Waters Hydrologic MUN AGR IND RECI REC2 WARM WILD Unit Number , 904.31 X X X X X X X 1.2.2 Groundwater Existing beneficial uses of groundwater for the project site in the Carlsbad Hydrologic Unit (904.31) includes municipal and domestic supply, agricultural supply and industrial service supply. None of these beneficial uses will be impaired or diminished due to the construction and operation of this project. Table 1.2 Beneficial Uses for Groundwater Hydrologic MUN AGR Unit Number 904.31 X * Excepted from Municipal x Existing Beneficial Use o Potential Beneficial Use Prepared -By Partners Planning and Engineering X IND X \\Server\c-drive\dwg\577\577 -swmp .doc 1/16/2006 I I I I I I I I I I I I I I I I I I I 2. CHARACTERIZATION OF PRO.JECT RUNOFF Runoff developed on site currently sheet flows from the northeast to the southwest to the existing desiltation basin located in the southwest corner of the site. The runoff is then conveyed via the existing public storm drain system to Agua Hedionda Creek. The proposed development will not significantly affect the current drainage pattern. Surface runoff from the developed site will be directed to either curb inlets or grated catch basins fitted with the Fossil Filtel:'M Storm Water Filtration System and then pass thru grass-lined swales for water quality purposes. In addition, on-site detention facilities will be located, where required, to reduce post development flows. Table 2.1 identifies the hydrologic/hydraulic characteristics for each basin. See Attachment 'B' for project BMP map. See Attachment 'C' for calculations. Table 2:1 BASIN Total Tc QIOO QWQ* Area Existing 9.97 AC 20.5 18.5 cfs 1.3 cfs BasinXA Min Developed 1.83 AC 13.7 4.1 cfs 0.22 cfs Basin A Min Developed 0.96 AC 7.7 4.4 cfs 0.16 cfs Basin B Min Developed 5.84AC 12.0 20.1 cfs 1.0 cfs Basin C Min Developed 1.27 AC 22~2 2.2 cfs 0.17 cfs Basin D Min * Based on 85 % percentIle storm wIth 1=0.2 m/hr 2.1 Expected Discharges There Was no sampling data available for the existing site condition. In addition, the project is not expected to generate significant amounts of non,..visible pollutants. However, the folloWing constituents are commonly found on similar developments from parking lot as identified in Table 2 of the City of Carlsbad's Standard Urban Storm Water Mitigation Plan: • Sediment discharge due to construction activities. • Nutrients from fertilizers. • Heavy metals from parked cars. • Trash and debris. • Oxygen demanding substances from landscaping and fertilizers. • Oil and grease from parked cars. ' • Pesticides from landscaping. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp,doc 1/16/2006 I I I I I I I I I I I I I I I I I I I 2.2 Pollutants of Concern According to the California 2002 303d list published by the San Diego Regional Water Quality Control Board, the only currently listed impaired water body associated with the Carlsbad Hydrologic Unit (HSA 904.31) is the Agua Hedionda Creek which is listed for Total Dissolved Solids, Bacteria Indicators and Sedimentation/siltation. No other water bodies are listed under the Carlsbad Hydrologic Unit (HAS 904.31). 2.3 Conditions of Concern Common impacts to the hydrologic regime resulting from similar developments include increased runoff volume and velocity; reduced infiltration; increased flow frequency, dliration and peaks; faster time to reach peak flow; and water quality degradation. In order to. mitigate these impacts, Bressi Ranch Development, LLC proposes to direct all surface runoff generated within the impervious areas through grass-lined trapezoidal channels designed at a slope to minimize potential scour and to maximize treatment efficiency. In addition, rip rap energy dissipaters will be placed at the channel outlets to reduce velocities to pre-existing levels. The proposed project will mitigate the pollutants of concern by fitting each of the proposed curb inlets and catch basins within the parking lot with the Fossil Filter™ Storm Water Filtration System for water quality purposes. In addition, on-site detention facilities will belocated, where required, to reduce post development flows to pre-existing conditions. Thus this project will not increase the amount of surface runoff directed towards Agua Hedionda Creek. There are pollutants that may be present in the surface runoff generated by the proposed improvements for the Bressi Ranch Lot 40 that could further impair the water quality of the receiving waters. Pollutants which cause impairment of receiving waters are considered primary pollutants of concern. Primary pollutants are: Nutrients from fertilizers Oxygen demanding substances Secondary Pollutants are: Sediment discharge due to construction activities Trash and debris Oil and grease from parked cars Pesticides from landscaping Heavy metals from parked cars Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp. doc 1/16/2006 I I I I I I I I I I I I I I I I I I I 3.0 MITIGATION MEASURES TO PROTECT WATER QUALITY To address water quality for the project, BMPs will be implemented during cOl1struction and post-construction. 3.1 Construction BMPs A detailed description of the construction BMPs has been developed with the Grading Plan Engineering. In addition to the BMPs listed on the Project Grading Plans, the following BMPs may also be used as required to the satisfaction of the City Engineer. • Silt Fence • Desilting Basin • Fiber Rolls • Gravel Bag Berm • Street Sweeping and Vacuuming • Sandbag Barrier • Storl11 Drain Inlet Protection • Material Delivery and Storage • Stockpile Management • Spill Prevention and Control • Solid Waste Management • Concrete Waste Management • Stabilized Construction Entrance/Exit • Water Conservation Practices • Dewatering Operations • Vehicle and Equipment Maintenance • Permanent Revegetation of all disturbed uncovered areas • Erosion Control Mats and Spray-on Applications Construction BMPs for this project will be selected, constructed, and maintained so as to comply with all applicable ordinances and guidance documents. A Storm Water Pollution Prevention Plan (SWPPP) will be prepared separately to, address the pollution prevention measures that will be taken during construction. 3.2 Post-construction BMPs 3.2.1 Site Design BMPs All disturbed areas will be either paved or landscaped. There will be no areas left bare. Landscaping of the proposed limits of disturbance is also incorporated into 'the plans. The landscaping will consist of both native and non-native plants. The goal is to achieve plant establishment expeditiously to reduce erosion. The irrigation system for these landscaped areas will be monitored to reduce over irrigation. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577-swmp.doc 1/16/2006 I I I I I I I I I I· I I I I I I I I I Project proponents shall implement Site Design concepts that achieve each of the following: 1) Minimize Urban Runoff 2) Minimize Impervious Footprint 3) Conserve Natural Areas 4) Minimize Directly Connected Impervious Areas (DC lAs) The project proponent should identify the specific BMPs implemented to achiev.e each Site Design concept and provide a brief explanation for those Site Design concepts considered not applicable. If a particular Site Design BMP concept is found to be not applicable, a brief explanation as to why the concept cannot be implemented will be provided. Also a narrative describing how each included BMP will be implemented will be provided. In those areas, where Site Design BMPs require ongoing maintenance. the inspection and maintenance fl'equency. the inspection criteria, and the entity or party responsible for implementation, maintenance, and/or inspection shall be described. Bressi Ranch Lot 40 site was designed to treat flow through BMP's implementations that include: Structural Detention Basin Grass line Swale Inlets fitted with fossil filters Structural detention basin was designed to minimize and convey the runoff flow during a 10-year stOlID and act as a structural BMP during the 85 th percentile storm. Grass line swales were designed to intervene the 85th percentile flow, increase the time of concentration and treat the flow prior to discharging the proposed development Only those catch basins in the onsite privately owned and maintained property shall have a fossil filter installed. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp. doc 1/16/2006 I I I I I I I I I I I I I I I I I I I Table 3.2.1.1 Site Design BMPs Design Technique Specific BMP Conce t Site Design !..:.!I1..:..:i.:..:n.:..:i1.:..:.11.:..::i='-'='e __ --"'U:..:...1':..:.;/JC""/c:.7, ; ". • Concept 1 Runoff Maximize the permeable area. lncorporate landscaped buffer areas between sidewalks and streets. Maximize canopy interception and water conservation by preserving existing native trees and shrubs, and planting additional native 01~ drought tolerant trees and large shrups. Use natural drainage systems. Where soils conditions are suitable, use perforated pipe or gravel filtration pits for low flow infiltration. Construct onsite ponding areas or retention facilities to increase opportunities for infiltration consistent with vector control objectives. Other comparable and equally effective site design concepts as approved by the Co-Permittee (Note: Additional narrative required to describe BMP and how it addresses Site Design concept). Included yes x x x x x Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 no x I I I I I I I I I I I I I I I I I I I Table 1. Site Design BMPs (Cont.) Design Concept Technique Specific BMP Included yes no Site Design Concept 1 Minimize Impervious .. ~:5 ,,::;' ',: ';' F ootpri nt r:-:-::-~~~--=-;"'O":;~""""'-~.:.;;..:.;--:....;;:...:..----:....::....---"-"--'-.:.....:....;....l...;"i'-'"''"'--'-~''--'-:;_:.:_-..:...:.;..;,;.;.~ Maximize the permeable area. Construct walkways, trails, patios, overflow parking lots, alleys, driveways, low-traffic streets and other low -traffic areas with open-jointed paving materials or permeable surfaces, such as pervious concrete, porous asphalt, unit pavers, and granular materials. Construct streets, sidewalks and parking lot aisles to the minimum widths necessary, provided that public safety and a walk able environment for pedestrians are not compromised. Reduce widths of street where off-street parking is available. Minimize the use of impervious surfaces, such as decorative concrete, in the landscape design. Other comparable and equally effective site design concepts as approved by the Co-Permittee (Note: Additional narrative required describing BMP and x x 1 ____ -+-_______ -+l'"710;.,.,w~it"'"'a;__d~d"....r~esses Site Design concept~).~~~ She Design Concept 1 Conserve Areas Prepared By Natural Partners Planning and Engineering Conserve natural areas. Maximize canopy interception and water conservation by preserving existing native trees and shrubs, and planting additional native or drought tolerant trees and large shrubs. Use natural drainage systems. Other comparable arid equally effective site design concepts as approved by the Co-Permittee (Note: Additional narrative required describing BMP and how it addresses Site Design concept). x \\Server\c-drive\dwg\577\577 -swmp,doc 1/16/2006 x x x I I I I I I I I I I I I I I I I I I I Table 1. Site Design BMPs (Cont.) Design Technique Concept Site -Minimize Directly Design Connected Concept 2 Impervious Areas (DCIAs) Prepared By Partners Planning and Engineering Included Specific BMP yes Residential and commercial sites mllst be designed X to contain and infiltrate roof runoff, or direct roof runoff to vegetative swales or buffer areas, where feasible. Where landscaping is proposed, drain impervious X sidewalks, walkways, trails, and patios into adjacent landscaping. Increase the use of vegetated drainage swales in X lieu of underground piping or imperviously lined swales. Rural swale system: street sheet flows to vegetated X swale or gravel shoulder, curbs at street corners, culverts under driveways and street crossings. Urban curb/swale system: street slopes to curb; X periodic swale inlets drain to vegetated swale/biofilter. Dual drainage system: First flush captured in X street catch basins and discharged to adjacent vegetated swale or gravel shoulder. Design driveways with shared . access, flared (single lane at street) or wheel strips (paving only under tires); or, drain into landscaping. Uncovered temporary or guest parking on private X residential lots may be paved with a permeable surface, or designed to drain into landscaping. Where landscaping is proposed in parking areas, X incorporate landscape areas into the drainage design. Overflow parking (parking stalls provided 111 excess of the Co-Permittee's minimum parking requirements) may be constructed with permeable paving. Other comparable and equally effective design concepts as approved by the Co-Permittee (Note: Additional narrative required describing BMP and' how it addresses Site Design concept). . , ';,', . \\Server\c-drive\dwg\S77\S77 -swmp.doc 1/16/2006 no X X X I I I I I I I I I I I I I I I I I I V.2 SOURCE CONTROL BMPs Table 2. Source Control BMPs BMP N~lme Non-Structural Source Control BMPs I) Education for Property Owners. Operators, Tenants, Occupants. or Employees 2) Activity Restrictions 3) Irrigation System and Landscape Maintenance 4) Common Area Litter Control 5) Street Sweeping Private Streets and Parking Lots 6) Drainage Facility Inspection and Maintenance Structural Source Control BMPs 7) Stenciling and Signage 8) Landscape and Irrigation System Design 9) Protect Slopes and Channels Provide Community Car Wash Racks Properly Design: Fueling Areas Air/Water Supply Area Drainage 10) Trash Storage Areas Loading Docks Maintenance Bays Vehicle and Equipment Wash Areas Outdoor Material Storage Areas Outdoor Work Areas or Processing Areas Provide Wash Water Controls for Food Preparation Areas Prepared By Partners Planning and Engineering Checl{ One Not Applic If not applicable, state Included able brief reason x x x x x x x x x x x x x x x. x x No community car wash racks on this site No fueling areas on this site No air/water supply area drainage on this site No mC\intenance bays on this site No vehicle and equipment wash areas on this site No outdoor material storage areas on this site No outdoor work areas X on this site No wash water areas X on this site \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 I I I I I I I I I I I I· I I I I I I I l. EDUCATION FOR PROPERTY OWNERS, OPERATORS, TENANTS, OCCUPANTS AND EMPLOYEES St Croix Capital shall provide a training package to all lessee. venders and contractors who will be performing maintenance or construction within the project site including but not limited to: -Lessee -Landscape Maintenance Company -HV AC Contractor -Building Maintenance Providers -Trash Collection Company St Croix Capital shall provide a training package at such time when the lessee occupies their specific space. Venders and contractors shall be provided a training package prior to the commencement of scope of work. The training material package shall include at a minimum the following items: -Color Exhibit showing the storm water layout and various components of the system. -City of Carlsbad Handout . -This manual 2. ACTIVITY RESTRICTIONS St Croix Capital shall develop use restrictions for all occupants/tenants through lease ten11s. The use restrictions include, but are not limited to, no outdoor storage of materials, no on-site car washing unless facilities available to capture a11 rinsate from the car wash, and no storage of hazardous materials on-site. 3. IRRIGATION SYSTEM AND LANDSCAPE MAINTENANCE St Croix Capital shall ensure to maintain all landscaping and irrigation facilities .. The operational and maintenance needs of the landscaping are: • Keep landscape areas in a neat and orderly condition. • Pick up garbage left within landscape areas. • Removal of all freshly trimmed landscape items and natural deposited items such as annual leaves and disposal off-site per governing codes. • Whenever possible use foliar/or soil nutrient testing before applying fertilizers to verify application timing and rate. • Use a higher percentage offeliilizers contain slow -release N, such as IBDU and sulfur- coated urea. Be aware hat organics (i.e. bone meal) and some slow-release fertilizers are dependent on microbial activity for the release of nitrogen; therefore low soil temperature will decrease the release of nitrogen available for plant uptake. • Ifhighly soluble-N fertilizers are used, apply smaller amounts on a more frequent basis. • Incorporate fertilizer directly into the soil around the plant, where possible, to mInimize potential surface runoff. • Although fertilizers must be watered in soil in order to work, the watering in should occur with light irrigation just after appl ication. Due to the unpredictability of rain events, it is recommended that fertilizers not be applied in the rain or on th~ siJme day that rain is expected. • Irrigation application rates and schedules should be adjusted to minimize surface runoff, especially immediately following the application of a fertilizer. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp. doc 1/16/2006 I I I I I I I I I I I I I I I I I I I • Immediately clean up any spill of fertilizers using dry methods of c1eat1 up such as by sweeping or scooping up material. . • Fertilizer storage facilities should be covered and have a impermeable foundation so that potential spills cannot runoff into surface water or leach into groundwater systems. • Fertilizers must be securely covered in the vehicle before being transported to application sites to avoid spillage or loss during transport. • Weed Control. Weeds will be removed through mechanical means. Herbicide will not be used because these chemicals may impact the water quality monitoring. • Thoroughly investigate and consider all leas toxic pest management practices. • Maintain a complete list of all pesticides used and the use site. • Use pesticides only according to label instructions. • Consider weather conditions that could affect application. For example, wind conditions affect spray drift; rain my wash pesticides off of leaves. • Do not apply pesticides where there is a high chance of movement into water bodies; for example, they should not be applied near wetlands, streams, lal,es, ponds or storm drains unless it is for an approved maintenance activity. . • In most cases, triple-rinse empty containers before disposal. Patticular information on the proper disposal of the pesticide and its container can be found 0 the label. • Never clean or rinse pesticide equipment and containers in the vicinity of storm drains or other open water areas. • Store pesticides in areas with cement floors and in areas insulated from temperature extremes. • Secure chemicals and equipment during transportation to prevent tipping or excess jatTing. • Pesticides must be transported completely isolated from people, food and clothing for example in the bed of the truck rather than in the passenger compartment. '. • Inspect pesticide equipment, storage containers and transportation vehicles frequently. • Develop a plan for dealing with pesticide spills and accidents. • Unless their safety is compromised, workers must immediately clean up any chemical spills according to label instructions and notify the appropriate supervisors and agencies. • Pesticide applications on public property, which takes place on school grounds, parks, 9r other public right-of -way where public exposure is possible, shall be posted with warning signs. • Broken sprinkler heads and/or lines will be repaired or replaced in a timely manner. • Periodic testing of all irrigation stations to verify if each landscape area is getting the correct amount of water. • Periodic testing of all flow reducers andlor shutoff valves to verify in good working order. Section 5.5. Hazardous Waste Suspected hazardous wastes will be analyzed to determine disposal options. Hazardous wastes generated onsite will be handled and disposed of according to applicable local, state. and federal regulations. A solid or liquid waste is considered a hazardous waste if it exceeds the ci·iteria listed in the CCR, Title 22, Article 11. . 4. COMMON AREA LITTER CONTROL St Croix Capital shall be responsible to implement trash management and litter control procedures in the common areas aimed at reducing pollution of drainage water. Trash receptacles shall be placed along traveled paths. Ash urns shall be placed at areas where Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 I I I I I I I I I I I I I I I I I I I smoking is allowed. The responsibilities shall include litter patrol, emptying of trash receptades in common areas and noting trash disposal violations. 5. STREET SWEEPING PRIVATE STREETS AND PARKING LOTS St Croix Capital shall be responsible to sweep the parking lots and private acces~ drives. 6. BMP MAINTENANCE St Croix Capital shall be responsible for implementation of each non-structural 8MP and scheduled cleaning andlor maintenance of all non-structural 8MP facilities. Detention Basin: The Detention Basin shall be visually inspected on a monthly basis for proper functionality. The basin shall be cleaned on a yearly basis. The basin shall have all trash and contaminates removed and disposed of off site per the City of Carlsbad Municipal code. The basin shall be inspected for worn or damaged parts. All worn or damage parts shall be replaced immediately. Inlet Inserts: Hydro-carbon filters shall be visually inspected for proper functionality. The filters shall be replaced. General Storm Drain: All storm drain facilities including inlets, pipes, Detention Basin, inserts shall be visually inspected yearly for damage or worn parts. 7. MS4 STENCILING AND SIGNAGE All storm water boxes (catch basins, inlets, etc) shall be stamped or stenciled. with prohibitive language (e.g., "No Dumping -I Live in the Santa Ana River") andlor graphical icons to discourage illegal dumping satisfactory to the City Engineer. If required, the stamping shall be in Spanish as well. The stamping or stenciling shall be maintained to remain legible. 8. LANDSCAPE AND IRRIGATION SYSTEM DESIGN Landscape and irrigation system was designed to ensure and implement the treatment of runoff flow. 9. PROTECT SLOPES AND CHANNELS The operational and maintenance needs to protect slopes and channels shall be: Convey runoff safely from the tops of slopes Avoid disturbing natural chatmels Stabilize disturbed slopes as quickly as possible Vegetate slopes with native or drought tolerant vegetation Control and treat flows in landscaping andlor other controls prior to reaching existing natural drainage systems. Stabilize 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 dissi paters, sllch 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. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 I I I I I I I I I I I I I I I I I I I 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 qual ity benefits fr0111 filtration and infiltration. If velocities in the channel are high enough to erode grass or other vegetative linings. riprap, concrete. soil cement, or geo- grid stabilization or other alternative. 10. TRASH STORAGE AREAS The operational and maintenance needs of trash storage areas shall be: The trash storage area shall be paved with an impervious surface, designed not to allow run-on from adjoining areas. The trash storage area shall be screened or walled to prevent off-site transport of trash. Use lined bins or dumpsters to reduce leaking of liquid waste. Provide roofs, awnings, or attached lids on all trash containers to minimize direct pI'ecipitation and prevent rainfall from entering containers. Pave trash storage areas with an impervious surface to mitigate spills. Do not locate storm drains in immediate vicinity of the trash storage area. Post signs on all dumpsters informing users that hazardous materials are not to be disposed of therein. The integrity of structural elements that are subject to damage (i.e., screens, covers, and signs) must be maintained by the owner / operator. Prepared By Partners Planning and Engineering \\SeNer\c-drive\dwg\577\577 -swmp.doc 1/16/2006 I I I I I I I I I I I I I I I I I I I 3.2.2 Source Control BMPs All hazardous materials with the potential to contaminate urban runoff shall be placed in an enclosure such as, but not limited to, a cabinet, shed or similar structure that prevents contact with rain, runoff or spillage to the storm water conveyance system. In addition. the hazardous materials enclosure shall be protected by secondary containment structure such as berms, dikes, curbs or temporary spill containment system. The storage area shall also be paved and sufficiently impervious to contain leaks and spills, and have a roof or awning to minimize direct precipitation within the secondary containment area. Trash storage areas shall be paved with an impervious surface, designed not to allow run-on fi'om adjoining areas and screened or walled to prevent off-site transport of trash; and centain attached lids on al,l trash containers that exclude rain or contain a roof or awning to minimize direct precipitation. Use of efficient irrigation systems shall be incorporated into the landscape design. Rain shutoff devices shall be employed to prevent irrigation after precipitation. In addition, the irrigation system shall be designed to meet each landscape area's specific water requirements consistent with the Carlsbad Landscape Manual. Finally, flow reducers or shutoff valves triggered by a pressure drop shall be used to control water loss in the event of broken sprinkler heads or lines. All storm water boxes (catch basins, inlets, etc) shall be stamped or stenciled with prohibitive language (e.g., "No Dumping -I Live Downstream") satisfactory to the City Engineer. The stamping or stenciling shall be located in the concrete pavement adjacent to the trench drains. If required, the stamping shall be in Spanish as well. The stamping or stenciling shall be maintained to remain legible. An additional Source Control BMP to be used on-site is good housekeeping. Good housekeeping practices that shall be utilized on site include keeping outdoor areas in a neat and orderly condition, picking up garbage left within the pavement and landscape areas. The site shall be visually inspected on a weekly basis to remove all "foreign" items including, but not limited to, landscape debris and common trash. Routine maintenance procedures for good housekeeping include removing all fi'eshly trimmed landscape items and natural deposited items such as annual leaves and dispose off-site per governing codes. In addition, during fertilizing, herbicide or pesticide application, over spray to non-landscape areas shall not be permitted. Application shall be limited to landscape area only. All fertilizer, herbicide or pesticide shall be applied in the amount and application as provided by the manufacturer. All empty containers shall be disposed of off-site per local codes. Finally, the paved areas shall be swept as necessary using dry methods (manual sweeping, street sweepers, etc) to remove dust and sediment buildup. Sweeping schedule to be determined by St Croix Capital. 3.2.3 Treatment Control BMPs As stated in Section III.2.D of the City of Carlsbad's Standard Urban Storm Water Mitigation Plan Storm Water Standards Manual, high priority projects shall include treatment control BMPs designed to infiltrate, filter andlor treat runoff from the project footprint to one of the "Sizing Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp,doc 1/16/2006 I I I I I I I I I I I I I I I I I I I Treatment Standards" listed in Table 3 of the Manual. The site design for Bressi Ranch Lot 40 will utilize both the Fossil Filter"M Storm Water Filtration System and bio-filtration (grass-lined swales) for water quality purposes. Both the Fossil Filter"M Storm Water Filtration System and grass-lined swales can cleanse the runoff generated by a storm event with a rainfall intensity of 0.2 inch/hour without impeding flow. 3.2.3. t Fossil Filtcr''M Storm Water Filtr~ltion System The Fossil Filter"M Storm Water Filtration System places a catch basin insert device that contains a filtering medium (a sorbent) just under the grates of the storm water system's catch basins-or just below the gutter flow line of the system's curb inlets. The water runoff ,flows into the inlet, through the filter where the target contaminants are removed, and then into the drainage system. An example of Fossil Filter™ Storm Water Filtration System is shown in Figure 3.1. The system effectively filters the first flush of storm water runoff from a storm event and provides an overflow capability sufficient to prevent the system from becoming clogged. The sorbent medium is a nonleaching inert blend of minerals that contain non-hazardous ingredients, as defined by Federal EPA, OSHA and WHO. 3.2.3.2 Vegetated Swales Vegetated swales are vegetated channels that receive directed flow and convey storm water. Vegetated strips are vegetated sections of land over which storm water flows as overland sheet flow. ,Pollutants are removed by filtration through the grass, sedimentation, adsorption to soil pmiicles, and infiltration through the soil. Swales are mainly effective at removing debris and solid particles, although some dissolved constituents are removed by adsorption onto the soiL See the Project Plan (Attachment 'B') for a cross-section of the proposed vegetated swales. 3.2.3.1.1 Appropri~te Applications and Siting Constraints Vegetated swales should be considered wherever site conditions and climate allow vegetation to be established and where flow velocities are not high enough to cause scour. Even where swales cannot be sited to accept directed sheet flow, vegetated areas provide treatment of rainfall and reduce the overall impervious surface. Factors Affecting Preliminary Design: Vegetated strips have two design goals: • Maximize treatment • Provide adequate hydraulic function for flood routing, adequate drainage and scour prevention. Treatment is maximized by designing the flow of water through the swale to be as shallow and long as site constraints allow. No minimum dimensions are required for treatment purposes, as this could exclude swales from consideration at some sites. Swales should also be sized as a conveyance system calculated according to City procedures for flood routing and SCOUI'. To maximize treatment efficiency, strips should be designed to be as long (in the direction of flow) and as Hat as the site will allow. No minimum lengths or maximum slopes are required for treatment purposes. Prepared By \\Server\c-drive\dwg\577\577-swmp,doc Partners Planning and Engineering 1/16/2006 I I I I I I I I I I I I I I I I I I I The area to be used for the strip should be fi'ee of gullies or rills that can concentrate overland flow and cause erosion. Table 3.2.1 summarizes preliminary design factors for vegetated swales. Table 3.2.1: Summary Of Bio-fiItnltion Design Factors (Strips And Swales) Description Applications/Siting Preliminary Design F'actors Swales are vegetated channels that • Site conditions • Swales sized as a conveyance receive and convey storm water. and climate allow sy;;tem (per City of Carlsbad Strips are vegetated buffer strips vegetation to be flood routing and scour over which storm water flows as establ ished proced ures) sheet flow. • Flow velocities • Swales sized as a conveyance Treatment Mechanisms: not high enough to system (per City of Carlsbad • Filtration through the grass cause seoul' tlood routing and scour • Sedimentation procedures) • Absorption to soil particles • Swale water depth as shallow • Infiltration as the site will permit Pollutants removed: • Strips sized as long (in • Debris and solid paI1icles direction oftlow) and tlat as • Some dissolved constituents the site allows • Strips should be free of gullies or rills • No minimum dimensjonsor slope restrictions for treatment purposes • Vegetation mix appropriate for climates and location Table 3.2.2: Criteria for Optimum Swale Performance Parameter Optimal Criteria Minimum Criteria Hydraulic Residence Time 9 minutes 5 minutes Average Flow Velocity 0.9 ft/sec Swale Width 8ft 2ft Swale Length 200 ft 100 ft Swale Slope 2-6% 1% Side Slope Ratio (Horizontal:vertical) 4:1 2:1 a e ~. . ropose rass wae er ormance . . T bl 323 P dG SIP ~ Basin Al A2 Prepared By Partners Planning and Engineering Time of Concentration (min) Length of SW111e (ft) -11 min -25 min 100 ft 100 ft \\Server\c-drive\dwg\577\577 -swmp, doc 1/16/2006 I I I I I I I I I I I I I I I I I I I 3.2.4 Target Pollutants and Proposed BMPs • Nutrients from fertilizers will be treated primarily by practicing and maintaining good housekeeping procedures and by the proposed Fossil Filtel:I'M Storm Water Filtration System and by the vegetated swales as secondary BMPs. • Trash and debris will be treated by practicing and maintaining good housekeeping procedures and by the proposed Fossil Filte/M Storm Water Filtration System as a secondary BMP. • Pesticides from landscaping will be treated by practicing and maintaining good housekeeping procedures. • Oxygen demanding substances from landscaping will be treated by practicing and maintaining good housekeeping procedures. ,. Oil and grease from parked cars will be treated by the proposed Fossil Filte/M Storm Water Filtration System and by the proposed vegetated swales. • Heavy metals from parked cars will be treated by the proposed Fossil Filter'IM Storm Water Filtration System and by the proposed vegetated swales. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp, doc 1/16/2006 I I I I I , I I I I I I I I I I I I I I MANHOLE CATCH BASIN (SEE NOTE 6) FILTER BODY FIL TER BASKET FOSSIL ROCK TflIL TER MEDIUM POUCH SIDE VIEW NTS CATCH BASIN CURB OPENING GUTTER FLOWLINE FLO-GARD FI fER BODY JIB" X J" ANCHOR BOLT (J PER SECT/ON) NO rES: ANCHOR DETAIL 1. FLO-(}ARDTIi FIL TER 80DY SHALL 8E MANUFACTUR£D FROM PETROLEUM RESISTANT FI8ER(}LASS MIlCH MEETS OR EXCEEDS PS 15-69. 2. ALL METAL COMPONENTS SHALL 8E STAINLESS STEfl (TYPE 304). J. REMOVA8LE FIL TER 8ASKfT SHALL 8E CONSTRUCTED FROM DURA8LE POL YPROPYLENE WOVEN MONOFILAMENT G£OTEXlILE. 4. FLO-(}ARDN FILTER 80DY SHALL 8E SECURED TO CATCH 8ASIN WALL mTH EXPANSION ANCHOR 80L TS AND WASHER (SEE DETAIL). 5. FLO-GARDN INSERTS AR£ AVAILA8LE IN 24" OR JO" L£NGTH SECTIONS AND MAY 8E INSTALLED IN VARIOUS COM81NA liONS (E.ND TO END) TO FIT MOST CATCH 8ASIS mDTHs. 6. AL TER BASK£T MA Y 8E REMOVED THROUGH CURB OPENING FOR EASE OF MAINTENANCE. 7. AL TER MEDIUM SHALL 8£ FOSSIL ROCK , IN DISPOSABLE POUCHES, INSTALLED AND MAINTAINED IN ACCORDANCE mTH MANUFACTUR£R RECOMMENDATIONS. FOSSIL FIL TER FLO-GARD SUPPLEMENTAL INSERT (PVT) CURB OPENING INLET 0Gu/ZE. 3, /.1 - - - - - - -_. ----~ _. - -.. ---. --.-- ST AINLESS STEEL SUPPORT FRAME CORNER SUPPORT BRACKETS NEOPRENE GASKET (HID SIDES) DURABLE \JOVEN MESH FILTER BODY' REPLACEABLE ADSORBENT-FILLE _ .,., POUCHES ~ .;j s: ~ (1\ VJ .. --('l SIL T AND DEBRIS CONTAINMENT AREAS REPLACE;ABL~ HIGH FLOW BYPASS TOP VIEW ~i .,9 e ADSORBENT-FILLED' SECTION VIEV. POUCHES MODULAR DESIGN FOR EASY REPLACEMENT OF FILTER COMPONENTS NOTES: 1. FLO-GAR'" FILTER BOOY IS PREFABRICATED FROM POLYPROPYLENE KQ~N MONOFILAMENT GEOTEX71Lf. 2. ALL METAL COMPONENTS SHALL BE STAINLESS STEEL (TYPE 304). J. REFER TO APPUCA 710N CHART FOR CATCH BASIN AND FlL TER SIZING. 4. FlL T£R MEDIUM SHALL BE FOSSIL ROCKlM, INSTALLED AND MAINTAINED IN ACCORDANCE ..,m MANUFACTURER RECOMMENDA nONs. 5. REFER· TO MANUFACTURER'S RECOMMENDATlONS FOR MAINTENANCE PROGRAM. 6. FLO-CAR'" INSERTS MA Y BE INSTALLED WITHOUT ADSORBENT POUCHES DURING COURSE OF CONSTRucnON AS A SEDIMENT A 710N CONTROL DEWCf. AFTER CONSTRucnON, REMO~ THE SEDIMENT AND INSTALL THE ADSORBENT POUCHES. FOR APPLICATION CHART SEE BELOW FOSSIL FIL TEA FLO-GARD CATCH BASIN INSERT I I I I I I I I I I I I I I I I I 'I I .' ··,·,.1,·· HYDRAULIC TESTING (Bypass Flow) o'! . Tests were conducted by consufting Civil Engineer and Hydrologist Mr. David Sandine of Sandine & Associates to determine maximum fiitration rates and now impediment during high flows using the Fossil RlterlN system. Installations and tests were conducted at the Petaluma Marina in Petaluma. California. INSTA lLA 1l0N 1 (FLAT GRATED DRAIN INLET): Single stage Fossil Filte(1W Hydrocarbon system installed into a flat grated drain inlet with an inside dimension of2r x 27". The installed square filter had total filter length of approximately 96" (8 nnear feet) and. atter ,installation, lett an open area high-now bypass in the center of approximately 16" x 16". INSTAlLATJON 2 (CURB INLET): . Dual stage Fossil FilterlN system installed in a City of Petaluma. standard curb ,.' r opening inlet with a curb opening width of 48" (4 linear feet). Two 48" (4 linear feet) straight filter rail sections were used, totaling 96" IiHer length (8 nnear feet). TEST 1 The first tests were conducted using a 450 GPM (1 CFS) flow rate to determine if the Fossil Filte("" would reduce the drainage inlet's hydraulic capacity in either of the above outlined installations. Results: A 450 GPM (1 CFS) flow rate showed no apparent restriction in flow. Equipment was not available to test assumed design hydraulic capacities greater than 1 CFS but it was apparent that the Fossil FilterTN could have handled a greater flow rate without overftow. TEST 2 The second set of tests were conducted on the dual stage curb opening installation (installation 2 above), using a metered fire hydrant to determine the flow rate at which overflow of both stages of the Fossi' FiHerTN would occur. The tests commenced with low velocity flows similar to those encountered' at the beginning of a rain event and then increased until overflow of the upper and then the lower stages occurred. Results: The dual stage Fossil FilterlN installed in the curb opening inlet effectively tiHered a flow rate up to 4S GPM before any bypass of the upper stage began at 92 GPM before bypass of the lower stage began. CONCLUSIONS These tests confirmed that the Fossil FinerN system is an effective method of fittering stormwater runoff during initial and low flows. Further, because of the bypass area designed into the Fossil FilterN. it will not restrict inlet capacity under high rate of now -even if the Fossil FifterTM itself becomes clogged. Note: Above testing performed on Original Hydrocarbon style filters. Test information on FIo-GardTW , Perk FilterThf and other Fossil FilterlM products http://www.kristar.comJ]evel2linfolinfoA3.html. -F/CfAl26-··":I.~ .... ~ .... -. 7/31/2002 I I I I I I I I I I I I I I I I I I I Best ~nagement ~ Practices ~: ~A BEST MANAGEMENT PRACTICE (8MP) FOR THE REMOVAL OF PETROLEUM HYDROCARBONS , SILT AND DEBRIS FROM STORMWATER RUNOFF THROUGH THE USE OF CATCH BASIN INSERT FILTRATION SYSTEMS The Concept of Stormwater Catch Basin Insert Filtration: Essentially, catch basin insert filtration is the placement of devices that contain a filtering medium (a sorbent) and a silt and debris containment area just under the grates of the stormwater system's catch basins. Placement of the devices at the entrance of the storm drain system provides the capability of removing all manner of pollutants from the runoff before they even enter the drainage system and have a chance to go underground and become saturated or emulsified. The water runoff flows into the inlet, through the filter where the sorbent's target contaminants, sediment and debris are removed~ and then into the drainage system. The devices must be capable of effectively filtering the first flush of a rain event and provide an overflow capability sufficient to prevent the system from becoming clogged. The sorbent filter medium must be an inert blend of minerals that contain non-hazardous ingredients, as defined by the Federal EPA, OSHA and WHO (World Health Organization). Further, the medium should be non-leaching, contain no reactive chemicals, be non- carcinogenic, non-biodegradable, non-toxic, non-inflammable and non-injurious to asphalt, cement, carpet, tile, soil, or plant life. Target Pollutants: The Catch Basin Filters should have a capability of capturing and retaining petroleum hydrocarbons and silt and debris. The sorbent's primary target contaminants are petroleum hydrocarbons, to include most, if not all, oil-based products generated by motor vehicles powered by fossil fuel or lubricated with any of the fossil fuel by-products. These include gasoline, oil, grease, some anti-freezes, and other such products plus other types of contamin~nts (Le. heavy metals) that may become attached through incidental capture to the hydrocarbon, silt and debris. The structure of the device should be capable of capturing and retaining silt, debris, litter, vegetation and other pollutants that may be bome by the runoff. The device should have at least one bypass capability in the event of heavy flows but yet be cabable of retaining floatables. Current Technology: Of the catch basin insert filtration systems currently on the market that target petroleum hydrocarbons, Flo-GardlM , a product of KriStar Enterprises of Sonoma County, California, is the most prominent. The Flo-GardlM introduced a concept that was unique enough to qualify for a U.S. patent. Prior to the introduction of Flo-Gard™ and its prececessor, the leading technology for separating oil from water runoff was large underground precast concrete oillwater separators. They were expensive to purchase and install and CGliid be used only on new construction projects. Generally because they were underground (and out of Sight). inspection was very difficult and maintenance was expensive. Consequently, they were usually forgotten and any pollutants collected were either transported to the receiving body of water or remained in the system to become emulsified into harmful nutrients and then flushed to the http://www.kristar.comlleve12/info/info B .html . --C) ..... .I. V.1. tot 1/22/2004 I I I I I I I I I I I I I I I I I I I ~ . --- _ ..... ----.~ ... _._ ........ ".""'4 .... ~... rage" ot-, receiving body of water with a future rain event. Also, absent, regular maintenance. and if standing water is allowed, water bearing systems can become a habitat for bacteria and insects (mosquitoes). Flo-Gard™, on the other hand, costs but a fraction of the concrete units to purchase and installation usually consists of removing the inlet grate, inserting the tilter and replacing the grate. They can be used in both new and post- construction projects; visual inspection is simple; and maintenance can be performed usually in a matter of minutes. Flo-Gard1ltl is availabe off the shelf for common size/shape inlets or can be fabricated for non-standard inlets. Models of the Flo-GardlM are available for square, rectangular, round and curb or combination inlets and trench drains. According to the manufacturer, a device to fit most any situation is possible. Device Construction: The catch basin filtration system structure should be constructed so as to cause the water to flow through the unit's filter medium (sorbent) and be of a fit that prevents leakage around the exterior of the filter. The device should have sediment and debris removal capabilities, the unit should also include a . containment area. To prevent corrosion and the release of oxidized metals into the system, all of the device's construction materials should be of high-density polyethylene (HOPE), petroleum-resistant fiberglass, stainless steel, or woven polypropylene monofilament geotextile. The use of galvanized stf~el should not be allowed. The inlet device should provide at least one bypass in the event of high nows; yet should have a built-in capability of retaining f10atables during bypass. . Recommended Effectiveness: Manufacturers of Catch Basin Filtration Systems, acceptable for installation, should be able to produce proof of appropriate laboratory or field testing of both the instal/ed sorbent and the structure itself. The tests should have demonstrated a capability of removing petroleum hydrocarbons and for containing other pollutants that enter the inlet plus proof that the device will not clog up the drainage system. Applicability of Devices to EPA's NPDES and SWPPP's: The Federal EPA's NPDES program, designed to control the discharge of pollutants to waters of the United States, cites a definition of oil/water separator as, "A device installed usually at the entrance to a drain, which removes oil and grease from water flows entering the drain". Catch Basin Filtration Systems acceptable for installation in petroleum hydrocarbon-generating areas should fit the federal EPA's definition of oillwater separator (above). Flo-Gard™ meets the EPA description plus it meets the. EPA mandate of BAT (Best Available, Technology) while being "economically feasible." Based on the foregoing. Flo-Gard TM is suitable for inclusion as a BMP in local SWPPP ·s. Plus, Flo-Gard™ has an added capability of removing sediment and debris from the runoff. Recommended Uses: Catch Basin Insert Filtration Systems should be required for aI/locations where petroleum hydrocarbons and sediment and debris are major sources of pollution to stormwater runoff and the water can be directed into a ~rainage inlet. Employee and customer parking lots, corporation yards, equipment http://www.kristar.comlleveI2/info/infoB.html 1/22/2004 I I I I I I I I I I I I I I I I I I I .-- ----------_ .. _ ... --_ .. -... -.. ..." ... service areas, toll-gates, refueling facilities areas are prime examples of such locations. They should be required for new construction a'nd whenever a permit is issued to renovate or remodel an existing location. Inspection and Maintenance Procedures: Each IIlspection of the installed filtration systems should include broom sweeping the area around the inlet, removal of the inlet grate, removal of trash and debris and visual inspection of the filter and its installed sorbent. The sorbent pouches should be removed, cleaned and insp~cted and, if .the media is more than 50% coated, new pouches should be installed. The deviCe should then be returned to its normal operating configuration, the intet grate replaced and another broom cleanup completed. The exposed filter media and collected debris should be placed in a DOT approved drum and disposed of in accordance with local agency requirements. Follow-On Maintenance: Because of past abuses of installed stormwater treatment devices, some governmental agencies within California, that accept Flo-Gard TM as a BMP for stormwater runoff r are· now requiring proof oe a· follow-on maintenance program. Other states are now following California's lead. It is recommended that the agencies require proof of either a contractor maintenance program or that the landowner certifies that they will provide maintenance, and the installations be made a component of periodic inspection tours. KriStar Enterprises, the manufacturers of Flo-Gard™, provides a , comprehensive maintenance program that not only provides for maintenance of all stormwater filtration systems (to include other than Flo-Gard™) but notifies the owner and the appropriate oversight agency when maintenance has been performed. Limitations: The efficiency of any filtration system is in direct proportion to the caliber of its maintenance program. Another system limitation is unsuitable installation sites. Examples of such sites would be areas with heavy leaf loading, areas next to sand or dirt piles and areas with permeable (non-hard) surface where soil and stones can be washed into the inlet. Recommendations: 1. That Catch Basin Filtration Systems such as Flo-Gard™ be included as a BMP for preventing pollution of stormwater runoff by petroleum hydrocarbons, silt and debris. 2. That new and post-construction projects in areas subject to the generation of petroleum hydrocarbons, silt and debris be surveyed as potential sites for installation of Catch Basin Insert Filtration Systems. Back to Top of Page http://www.kristar.comlleve12/info/infoB.html I: a.~t: J ot 4 112212004 I I I I I I I I I I I I I I I I I SUlJJPlary of ~ Tests A SUMMARY OF TESTS OF FLO-GARDTM AND OF FOSSIL ROCKTM This document summarizes tests and evaluations that have been conducted on Flo-Gard™ and Fossil RockTM , its installed adsorbent filter medium. The purpose of this document is to present a factual capsulization of the pertinent parts of several lengthy documents in one document. The tests were performed by the cited engineering finns, laboratories and other agencies. LABORATORY TESTING OF FOSSIL ROCKTM ADSORBENT 1. Prism Laboratory Tests: On November 28,1995, Prism laboratories of Charlotte, NC performed TClP (Toxicity Characteristic leaching Procedure) of . --_'0- Fossil Rock"'" , the adsorbent installed in Fossil Filters TM • Under laboratory conditions, testing was conducted with two [one] liter containers of water into which 50 drops of waster oil had been deposited. Liter A was tested for Method SW-846 #9070. Liter B was filtered through 10 grams of Fossil Rock™ and then used for TClP testing. Results: Fossil Rock™ from Liter A retained 98% of the waste oil. TClP testing after Liter B was filtered disclosed trace amounts of arsenic, selenium, cadmium, chromium lead, silver, mercury and barium at levels far below the , EPA limits. 2. Entech Lab Tests: In May 1996, Entech Analytical labs, Inc. of Sunnyvale CA conducted a lengthy series of tests of Fossil Rock"'" • An anal¥tical summary of the test results is as follows: Back to Top of Page Low level Contamination High Level Contamination Constituent After Treatment % Removal After Treatment Antimony 0.075 25% 9.55 Arsenic 0.029 71% 9.57 Barium 0.115 None 10.29 Beryllium 0.102 None 10.45 Cadmium 0.102 None 10.1 Chromium 0.094 6.0% 10.65 Cobalt 0.101 None 10.16 Copper 0.105 None 9.56 lead 0.097 3.0% 9.87 pc fAJZe "3,1.7 http://www.kristar.comfleveI2/info/infoA I.html % Removal 4.5% 4.3% None None None None None 4.4% 1.3% • "6'" 1 ur.! 1122/2004 J I I I I I I I ,I I I I I I ,I I I I I I Mercury 0.010 0 0.0047 99.5% Molybdenum 0.061 39.0% 9.2 8.0% Nickel 0.101 None 9.98 0.2% Selenium 0.119 None 11.21 None Silver 0.088 12.0% 6.21 31.9% Thallium 0.016 84.0% 10.79 None Vanadium 0.094 6.0% 9.95 0.5% Zinc 0.179 None 10.23 None Oil & Grease 3.6 55.0% 46.4 53.6% Motor Oil 0.052 94.8% 0.78 ,99.2% Diesel 0.014 98.6% 0.63 99.4% Gasoline 0.441 55.9% 34.8 65.2% 3. Fossil RocklM Characterization Project by Entech Labs, 'Inc. of, Sunnyvale CA Objective: Determine the ability of Fossil Rocknt to remove varying levels of a wide range of contaminants commonly found in industrial storm water discharges. Scope: Testing was conducted at High and Low relative concentrations for the following sets of contaminants: Diesel, Motor Oil, Gasoline, Oil & Greases and Heavy Metals. Results: (In % removal of contamination) are summarized in the table below: Contaminants Low Level High level Concentration Concentration Heavy Metals No Significant Change No Significant Change Gasoline 55.9% 65.2% Diesel 98.6% 99.4% Motor Oil 94.8% 99.2% Oil & Grease 55.0% 53.6% Conclusions: Based on the above testing: 1. Fossil Rock1M absorbs virtually all Diesel and Motor Oil presenUn water as it flows through the material. 2. Fossil Rock1M absorbs more than 50% of the Gasoline present in water as it flows through the material. 3. Fossil Rock 1M does not absorb significant amounts of Heavy Metals or Non- Petroleum based Oil & Grease as it flows through the material. ' U.C.L.A. TESTS OF FOSSIL FILTER FLO·GARDTM HIGH CAPACITY CATCH BASIN INSERT, CONDUCTED IN OCTOBER 2000 TESTING PROTOCOL: http://www.kristar.comlleve12/info/infoA 1.html 1/22/2004 I I I I I I I I I· I I I I I I I I I I Tap water from a three inch water line was metered into the system at a constant rate of 15 gallons per minute. The flow was regulated by a Doppler effect velocity meter, which measured the velocity of particles contained in the tap water. Small amounts of compressed air were injected into the ftowto simulate particles. The water then flowed through a stilling basin which allowed the pressure and velocity to decrease and dampen. The water then flowed by gravity through a 24 inch wide Hume to the catch basin. The contaminants (oil and grease) were then, by metering pump, released at a rate of 15 to 28 MG per liter of water into the ftume where the flowing conditions provided adequate mixing. The water flowed down the flume into the catch basin. The entire flow entered the catch basin through the insert: no flow was bypassed. Influent samples were collected in the water fall from the flume into the insert. Effluent. samples were collected by passing -a sampte"-container below the filter insert. The testing process involved two tests, the first for Percent Removal of Oil and Grease and the second for Total Oil and Grease Absorbed. Each of the two tests involved three sequence tests: The first was 30 minutes in duration, the second was also 30 minutes in duration and the third was three hours in duration for a total test-time of four hours. TEST RESULTS: PERCENT REMOVAL OF OIL AND GREASE IN THREE SEQUENCE TESTS First sequence of 30 minutes: The filter removed between 79% and 87% of the oil and grease with the higher rate occurring in the first 15 minutes of the test. Second sequence of 30 minutes: The filter removed between 69% and 89% of the oil and grease with the higher rate occurring during the second half of the period. Third sequence of three hours: The filter removed between 70% and 90% of the oil and grease at a uniform rate throughout the testing period. TOTAL OIL AND GREASE ABSORBED IN THREE SEQUENCE TESTS: At the end of the: First sequence of 30 minutes: The amount of oil and grease absorbed totaled approximately 20,000 mg; Second sequence 0(,30 minutes: The amount of oil and grease absorbed totaled approximately 65,000 mg; Third sequence of three hours: The amount of oil and grease absorbed totaled approximately 300,000 mg of oil and grease. Note: The above testing protocol for tests of the Fossil Filter Flo-Gard High Capacity catch basin inserts was developed, and the October 2000 tests performed, by Professor Michael Stenstrom of the University of California at Los Angeles Back to Top of Page -----------._----- http://www.kristar.comlleve12!info/infoA 1.html 1122/2004 I I I I I I I I I I I I I I I I I I I 4.0 OPERATION AND MAINTENANCE PROGRAM The operation and maintenance requirements for each type of BMP are as follows: 4.1 Source Control BMPs 4.1.1 H~lzurdous Mutcrial Storage Hazardous materials with the potential to contaminate urban runoff shall be: .• Placed in an enclosure such as, but not limited to a cabinet, shed, or similar structure that prevents contact with rain, runoff or spillage to the storm water conveyance system. • Protected by secondary containment structures such as berm, dikes, or curbs. • The storage shall be paved and sufficiently impervious to contain leaks and spills. • The storage shall have a roof or awning to minimize direct precipitation within the secondary containment area. 4.1.2 Trash Stornge The operational and maintenance needs of trash storage shall be: • The trash storage area shall be paved with an impervious surface, designed not to allow run-on from adjoining areas. • The trash storage area shall be screened or walled to prevent off-site transport of trash. • All trash containers shall contain lids that exclude rain. 4.1.3 Efficient Irrigation System The operational and maintenance needs of an irrigation system are: • Preventive maintenance and visual inspection of all sprinkler heads and lines. • Periodic testing of all irrigation stations to verify if each landscape area is getting the correct amount of water. • Periodic testing of all flow reducers and/or shutoff valves to verify in good working order. Inspection Frequency The facility will be inspected and inspection visits will be completely documented: • Once a month at a minimum or as directed by the City of Carlsbad. Aesthetic and Functional Maintenance Both forms of maintenance will be combined into an overall Stormwater Management System Maintenance. Aesthetic Maintenance The following activities will be included in the aesthetic maintenance program: • Broken sprinkler heads and/or lines will be repaired or replaced in a timely manner. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp .doc 1/16/2006 I I I I I I I I I I I I I I I I I I I Functional Maintenance Functional maintenance has two components: Preventive maintenance Corrective maintenance Preventive Maintenance Preventive maintenance activities to be instituted for an irrigation system include: • Preventive maintenance and visual inspection of all sprinkler heads and lines. • Periodic testing of all irrigation stations to verify if each landscape area is getting the COl1'ect amount of water. • Periodic testing of all flow reducers and/or shutoff valves to verify in good working order. C011'ective Maintenance Corrective maintenance is required on an emergency or non-routine basis to correct problems and to restore the intended operation and safe function of an irrigation system. Corrective maintenance activities include: • Broken sprinkler heads and/or lines will be repaired or replaced in a timely manner. • General Facility Maintenance. In addition to the above elements of corrective maintenance, general corrective maintenance will address the overall irrigation system and its associated components. If corrective maintenance is being done to one component, other components will be inspected to see if maintenance is needed. . 4.1.4 Inlet / Catch Basin Tiles The precast concrete grated catch basins shall be adorned with tiles containing prohibitive language and/or icons to discourage illegal dumping. The legibility of the tiles will be maintained and they will be placed flush with the top of the concrete to reduce tripping by pedestrians. All tiles shall be inspected at least once a month or as directed by the City of Carlsbad. Should the legibility of the tile be in question, then the tile shall be repaired or replaced to restore full legibility. 4.1.5 Good Housekeeping The operational and maintenance needs associated with good housekeeping are: • Keep outdoor areas in a neat and orderly condition. • Pick up garbage and/or animal fecal waste left within the pavement and landscape areas. • Periodic sweeping of the paved areas. • Removal of all freshly trimmed landscape items and natural deposited items such as annual leaves and disposal off-site per governing codes. • Apply all fertilizer, herbicide or pesticide in the amount and application as. provided by the manufacturer. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 I 1 1 I I 1 1 1 1 I 1 I I I 1 1 I· 1 1 Inspection Frequency The site will be inspected and inspection visits will be completely docllmented: • On a weekly basis or a directed by the City of Carlsbad Aesthetic and Functional Maintenance Both forms of maintenance will be combined into an overall Stonnwatel' Management System Maintenance. Aesthetic Maintenance The following activities will be included in the aesthetic maintenance program: • Keep outdoor areas in a neat and orderly condition. • Pick up garbage andlor animal fecal waste left within the pavement and landscape areas. • Periodic sweeping of the paved areas. • Removal of all freshly trimmed landscape items and natural deposited items sllch as annual leaves and disposal off-site per governing codes. • Weed Control. Weeds will be removed through mechanical means. Herbicide will not be used because these chemicals may impact the water quality monitoring. Functional Maintenance Functional maintenance has two components: Preventive maintenance Corrective maintenance Preventive Maintenance Preventive maintenance activities to be instituted with good housekeeping are: • Apply all fertilizer, herbicide or pesticide in the amount and application as provided by the manufacturer. Corrective Maintenance Corrective maintenance is required on an emergency or non-routine basi.s.Corrective maintenance activities include: • General Facility Maintenance. General corrective maintenance wUI address the overall facility and its associated components. If corrective maintenance is being done to one component, other components will be in~pected to see if maintenance is needed. Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 I I I I I I I I I I I I I I I I I I I 4.2 Treatment Control BMPs 4.2.1 Fossil FiIter™ Storm Water Filtration System The operational and maintenance needs of a Fossil Filter'lM Storm Water Filtration System are: • Removal of contaminants, sediments and debris from stormwater runoff. • Absorption of petroleum hydrocarbons and oil-based products from stormwater runoff. Inspection Frequency The Fossil Filte/M Storm Water Filtration System will be inspected on a regular basis. The frequency of inspection would be based on pollutant loading, amount of debris, leaves, etc., and amount of runoff. The manufacturer's recommendations include no less than three inspections per year. Manufacturer guidelines for inspection frequency are: • For areas with a definite rainy season: Prior to and during the rainy season. • For areas subject to year-round rainfall: On a recurring (preferably scheduled) basis. • For areas with winter snow and summer rain: Prior to and just after the snow season and during the summer rain season. • For filters not subject to the elements (wash racks, parking garages, etc.): Inspections should be on a regular basis. Aesthetic Maintenance The parking lot will be swept on a regular basis. Sediment ai1d debris (litter, leaves, papers, cans, etc.) within the area and especially around the drainage inlet will be collected and removed Preventive Maintenance Preventive maintenance for the FloGard'l'M Storm Water Filtration System will be: • After broom sweeping and removal of debris around the inlet, the catch basin grate will be removed and the condition of the screens will be checked. • For Hydrocarbon units with screens covering the adsorbent, the condition of the screen will be checked and the adsorbent will be inspected through the screen. If excessive silt covers the top of the adsorbent or if the adsorbent granules are more than one-half coated with a dark gray or black substance, the adsorbent will be replaced. • For FloGard'lM units with adsorbent pouches, the condition of the pouches will be checked and a visual inspection made of the enclosed adsorbent. If the granules are coveted, the pouches will be replaced. • For Flo-Gard'IM filters, which have a fabric filter body, the serviceability of the fabric will be determined and, if called for, replaced with a new one. I I I I I I I I I I I I I I I I I I I Corrective Maintenance Corrective maintenance is required when the exposed adsorbent filter medium needs to be replaced. To replace the filter medium, the steps are: • To avoid spilling the exposed adsorbent filter medium into or onto the surrounding surface, the person replacing the adsorbent should move away from the inlet and work over a large work cloth. • All exposed adsorbent and collected debris must be dumped into a D.O.T.-approved container for later disposal. The method of replacing the adsorbent depends on the type of filter. • For filters with removable filter cartridges, the cartridges need to be removed from the filter, the end caps r~moved and the exposed material poured out. The new adsorbent will be poured into the adsorbent containment area to a level about 1 Y2 inches from th~ top . screen when the filter cartridge or filter is level. • For filters with one-piece top screens, the entire filter needs to be removed to Hie work area, the top screen removed and the exposed material poured out. The new adsorbent will be poured into the adsorbent containment area to a level about 1 Yz inches from the top screen when the filter cartridge or filter is level. • For filters with adsorbent pouches, the pouches need to be removed and disposed of. The new adsorbent pouches are snapped into place. Disposal of Exposed Adsorbent, Debris and Trash The exposed adsorbent, debris and trash that is generated, will be properly disposed of by St Croix Capital. • The exposed adsorbent is non-biodegradable, non-leaching and non-cai'cinogenic so, with proper handling and documentation, it can be disposed of at a landfill. However, because disposal regulations vary by area, St Croix Capital will contact their local regulatory agency and landfill to ensure compliance with local and state environmental regulations. Hazardous Waste Suspected hazardous wastes will be analyzed to determine disposal options. Hazardous wastes generated onsite will be handled and disposed of according to applicable local, state, and federal regulations. A solid or liquid waste is considered a hazardous waste if it exceeds the criteria listed in the CCR, Title 22, Aliicle 11. . I I I I I I I I I I I I I I I I I I I Stormwater runoff occurs when precipitation from rain or snowmelt flows over the ground. Impervious surfaces like driveways, sidewalks, and streets prevent stormwater from naturally soaking into the ground. Storm water can pick up debris, chemicals, dirt, and other pollutants and flow into a storm sewer system or directly to a lake, stream, river, wetland, or coastal water. Anything that enters a storm sewer system is discharged untreated into the waterbodies we use for swimming, fishing, and providing drinking water. Polluted stormwater runoff can have many adverse effects on plants, fish, animals, and people. • Sediment can cloud the water and make it difficult or impossible for aquatic plants to grow. Sediment also can ' destroy aquatic habitats. • Excess nutrients can cause algae blooms. When algae die, they sink to the bottom and'decompose in a process that removes oxygen from the water. Fish and other aquatic organisms can't exist in water with low dissolved oxygen levels. • Bacteria and other pathogens can wash into swimming areas and create health hazards, often making beach closures necessary. • Debris-plastic bags, six-pack rings, bottles, and cigarette butts-washed into waterbodies can choke, suffocate, or disable aquatic life like ducks, fish: turtles, and birds. • Household hazardous wastes like insecticides, pesticides, paint, solvents, used motor oil, and other auto fluids can poison aquatic life. Land animals and people can become sick or die from eating diseased fish and shellfish or ingesting polluted water. • Polluted storm water often affects drinking water sources. This, in turn, can affect human health and increase drinking water treatment costs. I I I I I I I I I I I I I I I I I I I Rergrh O't pwpeJg dlJpDl.I!E of kw.elwld prwditill t/rot eo«1D.u~ rk«itdJ, .uek, a! ill4eetleufet., Pel,1leJdel" pau<t 4dvelili., ov.d w.ed #w1:ct ud ov.d utfta rui!U r&d. Washing your car and degreasing auto parts at home can send detergents and other contaminants through the storm sewer system. Dumping automotive fluids into storm drains has the same result as dumping the materials directly into a waterbody. • Use a commercial car wash that treats or recycles its wastewater. or wash your car on your yard so the water infiltrates into the ground. Dol{, 't prxa "fh",. IlIi1ir t/te glf./XlJld IJ'(, UiJh lfiJ'TJj~ d;roim,. Lawn care Excess fertilizers and pesticides applied to lawns an_d gardens wash off and pollute streams. In addition, yard . clippings and leaves can wash into storm drains and contribute nutrients and organic matter to streams. • Don't overwater your lawn. Consider using a soaker hose instead of a sprinkler. • Use pesticides and fertilizers sparingly. When use is necessary, use these chemicals in the recommended amounts. Use organic mulch or safer pest control methods whenever possible. • Compost or mulch yard waste. Don't leave it in the street or sweep it into storm drains or streams. • Cover piles of dirt or mulch being used in landscaping projects. • Repair leaks and dispose of used auto fluids and batteries at designated drop-off or recycling locations. Septic systems Leaking and poorly maintained septic systems release nutrients and pathogens (bacteria and viruses) that can be picked up by stormwater and discharged into nearby waterbodies. Pathogens can cause public health problems and environmental concems. • Inspect your system every 3 years and pump your tank as necessary (every 3 to 5 years). • Don't dispose of household hazardous waste in sinks or toilets. Pet waste Pet waste can be a major source of bacteria and excess nutrients in local waters. • When walking your pet. remember to pick up the waste and dispose of it properly. Flushing pet waste is the best disposal method. Leaving pet waste on the ground increases public health risks by allowing harmful bacteria and nutrients to wash into the storm drain and eventually into local waterbodies. Permeable Pavement-Traditional concrete and asphalt don't allow water to soak into the ground. Instead these surfaces rely On storm drains to divert unwanted water. Permeable pavement systems allow rain and snowmelt to soak through. decreasing stormwater runoff. Rain Barrels-You can collect rainwater from rooftops in mosquito- proof containers. The water can be used later-on lawn or garden areas. Rain Gardens and Grassy Swales-Specially designed areas planted with native plants can provide natural places for rainwater to collect and soak into the ground. Rain from rooftop areas ot paved areas can be diverted into these areas rather than into storm drains. Vegetated Filter Strips-Filter strips are areas of native grass or plants created along roadways or streams. They trap the pollutants stormwater picks up as It flows across driveways and streets. Dirt. oil. and debris that collect in parking lots and paved areas can be washed into the storm sewer system and eventually enter local waterbodies. • Sweep up litter and debris from sidewalks. driveways and parking lots. especially around storm drains. Erosion controls that aren~t maintained can cause excessive amounts of sediment and debris to be carried into the stormwater system. Construction vehicles can leak fuel. oil. and other harmful fluids that can be picked up by stormwater and deposited into local waterbodies. • Divert stormwater away from disturbed or exposed areas of the construction site. • Cover grease storage and dumpsters and keep them clean to avoid leaks. • Report any chemical spill to the local hazardous waste cleanup team. They'lI know the best way to keep spills from harming the environment. • Install silt fences. vehicle mud removal areas. vegetative cover. and other sediment and erosion controls and properly maintain them. especially after rainstorms. • Prevent soil erosion by minimizing disturbed areas during construction projects. and seed and mulch bare areas as soon as possible. Lack of vegetation on stream banks can lead to erosion. Overgrazed pastures can also contribute excessive amounts of sediment to local waterbodies. Excess fertilizers and pesticides can poison aquatic animals and lead to destructive algae blooms. Uvestock in streams can contaminate waterways with bacteria. making them unsafe for human contact. -• Keep livestock away from streambanks and provide them a water source away from waterbodies. • Store and apply manure away from waterbodies and in accordance with a nutrient management plan. • Vegetate ripanan areas along waterways. • Rotate animal grazing to prevent soil erosion in fields. • Apply fertilizers and pesticides according to label instructions to save money and minimize pollution. Improperly managed logging operations can result in erosion and sedimentation. • Conduct preharvest planning to prevent erosion and lower costs. t Use logging methods and equipment that minimize soil disturbance. • Plan and design skid trails. yard areas. and truck access roads to minimize stream crossings and avoid disturbmg the forest floor. • Construct stream crossings so that they minimize erosion and physical changes to streams. • Expedite revegetation of cleared areas. Uncovered fueling stations allow spills to be washed into storm-drains. Cars waiting to be repaired can leak fuel. oil, and other harmful fluids that_can be picked up by stormwater. • Clean up spills immediately and properly dispose of cleanup materials. • Provide cover over fueling stations and design or retrofit facilities for spill containment. • Properly maintain fleet vehicles to prevent oil. gas. and other discharges from being washed into local waterbodies. • Install and maintain Oil/water separators. ------------------ Use These Guidelines For Outlioo'ltci(=anlnlfActlvlties~iln-lfwa'shwaler"DisPOSIII" Do . . . Dispose of small amounts of washwater from cleaning building exteriors, sidewalks, or plazas onto landscaped or unpaved surfaces provided you have the owner's permission and the discharge will not cause flooding or nuisance problems, or flow Into a storm drain. Do . . . Check with your local sewering agency's policies and requirements concerning waste water disposal. Water from many outdoor cleaning activities may be acceptable for disposal to the sewer system. See the list on the back of this flyer for phone numbers of the sewering agencies in your area. Do ... Understand that water (without soap) used to remove dust from clean vehicles may .be discharged to a street or storm drain, Washwater from sidewalk, plaza, and building surface cleaning may go Into a street or storm drain if ALL of the following conditions are met: 1) The surface being washed is free of residual oil stains, debris and similar pollutants by using dry cleanup methods (sweeping, and cleaning any oil or chemical spills with rags or other absorbent materials before using water). 2) Washing is done with water only -no soap or other cleaning materials, 3) You have not used the water to remov'e paint from surfaces during cleaning. Do . . . Understand that mobile auto detailers should divert washwater to landscaped or dirt areas. Note: Be aware that soapy washwater may adversely affect landscaping; consult with the property owner, Residual washwater may remain on paved surfaces to evaporate; sweep up any remaining residue. If there is sufficient water volume to reach the storm drain, collect the runoff and obtain permission to pump it into the sanitary sewer. Follow local sewering agency's reqUirements for disposal. Regarding Cleaning Agents: If you must use soap, use biodegradable/phosphate free cleaners. Avoid use of petroleum based cleaning products. Although the use of nontoxic cleaning products is strongly encouraged, do understand that these products can still degrade water quality and, therefore, the discharge of these products into the street, gutt~rs, storm drain system, or waterways is prohibited by local ordinances and the State Water Code. Note: When cleaning surfaces with a high pressure washer or steam cleaning methods, additional precautions should be taken to prevent the discharge of pollutants into the storm drain system. These two methods of. surf?ce cleaning, as compared to the use of a low pressure hose, can remove additional materials,that can contamfnate local waterways. OTHER TIPS TO HELP PROTECT OUR WATER. • • • SCREENING WASH WATER DRAIN INLET PROTECTION! CONTAINING & COLLECTING WASH WATER EQUIPMENT AND SUPPLIES - I I I I I I I I I I I I I I I I I I I 5.0 FISCAL RESOURCES St Croix Capital is aware of its responsibility to maintain all construction and post-construction BMPs to ensure they are all in good working order. St Croix Capital agrees to enter into a contract with the City of Carlsbad obliging Bressi Ranch Lot 40 to maintain, repair and replace the storm water BMPs as necessary into perpetuity. As part of this contract, St Croix Capital agrees to prepare an Operation & Maintenance Plan (0 & M) satisfactory to the City Engineer as an attachment to the contract. St Croix Capital is aware that the 0 & M plan shall describe the designated responsible party to manage the storm water BMPs, employees training program and duties, operation schedule, maintenance frequency, routine service schedule. specific . maintenance activities, copies of resource agency permits and any other necessary activities. St Croix Capital understands that at a minimum the 0 & M plan shall require the inspection and servicing of all structural BMPs on an annual basis, that all maintenance requirements shall be documented, that all maintenance records shall be retained for at least five years and that all documents shall be made available to the City for inspection upon request at any time. In addition, St Croix Capital is aware that security may be required. 6.0 CONCLUSIONS The proposed development of Bressi Ranch Lot 40 should not adversely impact the beneficial uses of the Batiquitos Hydrologic Subarea of the San Marcos Hydrologic Area (HSA 904.51)of the Carlsbad Hydrologic Unit. In order to minimize water quality impacts ass~ciated with development, St Croix Capital will institute site design, source control and treatment control BMPs as identified in Section 3.2 of this report. The target pollutants generated by this site and the proposed BMPs to treat them area as follows: • Nutrients from fertilizers will be treated primarily by practicing and maintaining good housekeeping procedures and by the proposed Fossil Filter™ Storm Water Filtration System and by the vegetated swales as secondary BMPs. • Trash and debris will be treated by practicing and maintaining good housekeeping procedures and by the proposed Fossil Filter'IM Storm Water Filtration System as a secondary BMP. • Pesticides from landscaping will be treated by practicing and maintaining good housekeeping procedures. • Sediment discharge due to construction activities will be treated by the use of silt fence, stockpile management, stabilized construction entrance/exit, erosion control mats and spray-on applications, gravel bag barriers and permanent revegetation of all disturbed uncovered areas. • Oxygen demanding substances from landscaping will be treated by practicing and maintaining good housekeeping procedures. • Oil and grease from parked cars will be treated by the proposed Fossil Filter'IM Storm Water Filtration System and by the proposed vegetated swales. • Heavy metals from parked cars will be treated by the proposed Fossil FiIterl'M Storm Water Filtration System and by the proposed vegetated swales. I I I I I I I I I I I I I I I I I I I Although none of the BMPs chosen are rated as having a High Removal Efficiency, St Croix Capital believes that it has addressed the water quality isslies to the maximum extent practicable considering the size of this site and the amount of runoff generated. I I I I I I I I I I I I I I I I I I I This Storm Water Management Plan (SWMP) has been prepared under the directi0n of the following Registered Civil Engineer. The Registered Civil Engineer attests to the technical information contained herein and the engineering data upon which recommendations, conclusions, and decisions are based. Andrew J. Kann REGISTERED CIVIL ENGINEER Date RCE 50940 I I I ATTACHMENT A I VICINITY MAP I I I I I I I I I I I I I I I I I I I I I I I I ( , I I I I , I I I I I I ( VICINITY MAP PACIFIC OCEAN ~----1 CITY OF VISTA VICINITY MAP NOT TO SCALE I I ATTACHMENT B I PROJECT MAP I . I I I I I I I I I I I I I I I I I I ATTACHMENT C I CALCULATIONS I I I I I . I I I I I I I I I I I Ii Ii Ii I I I I I I I I I I I I I I I STORM DRAIN REPORT FOR Bressi Ranch Lot 40 Carlsbad, California January 13, 2006 DWG No. 935-3A Project No. CT-05-07 Prepared By: PARTNERS Planning and Engineering 15938 Bernardo Center Drive San Diego, CA 92127 (858) 376-3444 50940 I , ·If It It I I I I I I I I I I I I I I I TABLE OF CONTENTS SITE AND PROJECT DESCRIPTION METHODOLOGY EXISTING CONDITIONS DEVELOPED CONDITIONS EXISTING RUNOFF ANALYSIS DEVELOPED RUNOFF ANALYSIS CURB INLET DESIGN AND ANALYSIS CULVERT DESIGN AND ANALYSIS CHANNEL DESIGN AND ANALYSIS DETENTION BASIN DESIGN AND ANALYSIS RESULTS AND CONCLUSIONS LIST OF FIGURES FIGURE 1: VICINITY MAP FIGURE 2: PROPOSED HYDROLOGY MAP FIGURE 3: EXISTING HYDROLOGY MAP LIST OF TABLES TABLE 1: HYDROLOGY/INLET SUMMARY· TABLE 2: HYDROLOGY AND HYDRAULIC CALeS LIST OF APPENDICES Appendix 1: Runoff Coefficients Appendix 2: 100-Year, 10-Year & 2-Year Isopluvial Charts Appendix 3: Intensity -Duration Design Chart Appendix 4: Gutter & Roadway Discharge -Velocity Chart Appendix 5: Overland Time of Flow Nomograph Appendix 6: Handbook of Hydraulics Tables 7-4, 7-11 and 7-14 page 1 page 1 page 1 page 1 page 2 page 2 page 2 page 2 page 3 page 3 page 3 page 4 attached attached pageS page 6 I I I I I I I I I I I I I I I I I I I SITE AND PROJECT DESCRIPTION This storm drain report has been prepared as part of the Development Permit submittal .. requirements for the development of Bressi Ranch Lot 40. The proposed development includes fifteen (15) office buildings with associated parking. landscaping and hardscape. The project site is located east of Interstate 5 and south of Palomar Airport Road. See Figure No. I for Vicinity Map. See Figure 2 attached at the end of this report for the proposed . drainage limits. See Figure 3 attached at the end of this report for the existin.g drainage limits. METHODOLOGY This drainage report has been prepared in accordance with current City of Carlsbad regulations and procedures. AlI of the proposed pipes, curb inlets and grass-lined swaies were designed to intercept and convey the 1 OO-year storm. The Modified Ration&l Method was used to compute the anticipated runoff. See the attached calculations for particulars. The following references have been used in preparation of this report: . (1) San Diego Countv Hvdrologv Manual, June, 2003. (2) Handbook of Hydraulics, E.F. Brater & H.W. King, 6th Ed., 1976. EXISTING CONDITIONS: The proj ect site lies within the Bressi Ranch Industrial Park south of Palomar Airport Road. The existing site currently consists of a mass graded pad with a desiltatibn basin located in the southwest corner of the site. Runoff developed on site currently sheet flows from the northeast to the southwest to the existing desiltation basin. Pipe No.6 (30" RCP) per City of Carlsbad Dwg No. 400-8D sheet 9 (see attached exhibit) is designed to account up to 37.73 cfs at a velocity of 7.70 fps. DEVELOPED CONDITIONS: The proposed development includes fifteen (lS) office buildings with associated parking, landscaping and hardseape. Surface runoff from the site will be directed to either curb inlets or grated catch basins fitted with the Fossil Filter'·" Storm Water Filtration System or grass- lined swales for water quality purposes. In addition, on-site detention facilities will be located, where required, to reduce post development flows. Proposed development cannot exceed discharge of 18.5 cfs in order to match existing conditions per Partners Planning and Engineering calculations. The emergency overflow is incorporated in th~ water quality/ detention basins with 'f catch basins. The 'f catch basins are designed to accept the emergency overflow. Storm drain system pipe no 6 (30" Rep) on Gateway Road is designed to account up to 37.73 efs per City of Carlsbad Dwg No. 400-8D sheet 9 (see attached exhibit). I I I I I I I I I I I I I I I I I I I EXISTING RUNOFF ANALYSIS: The site sheet flows from northeast to southwest towards the existing desiltation basin located at the southwest corner of the site. A runoff coefficient of 0.65 would be appropi'iate for the mass graded pad. See Table 1 as well as the attached calculations for particulars. DEVELOPED RUNOFF ANALYS1S: All of the proposed pipes, inlets and catch basins were designed to intercept and convey the 1 aD-year storm. The runoff coefficients for the site were based on soil group D and ultimate improvements for the proposed site. Runoff coefficients used for the proposed analysis ranged from 0.52 to 0.89 for the Basins. All of the proposed drainage culverts will be PVC and were sized using a Manning's 'n' coefficient of 0.013. Runoff from the site wi-ll be directed to one of three (3) water quality basins located along the southerly boundary of the project site. See Table 1 as well as the attached calculations for particulars. CURB INLET DESIGN AND ANAL YS1S: The proposed curb inlets are located in a sump condition. The curb inlets were sized utilizing. the "Nomogram-Capacity, Curb Inlet at Sag" assuming a 1 O-inch curb. faQe with a 6.2-inch curb opening at the inlet to determine the capacity per foot of opening (Q/L) in cfs per foot. The clear opening length was then calculated using the following equation: L = Q / (Q / L) where L = Length of clear opening in feet QlOo/L = Capacity per foot of opening from Nomogram To obtain the inlet length as shown on the Grading Plans for this project, one foot was added to the clear opening lengths. . CULVERT DESIGN AND ANALYSIS: The storm drain culverts were sized using King's handbook (Reference 3) Table 14 to verify capacity. For circular conduits: K' = Qn/ld"(S/3)sA(1I2)] where K' = Discharge Factor Q = RUDOffDischarge Ccfs) n = Manning"s Coefficient d = Diameter of Conduit (ft) s = Pipe Slope (ft/ft) See the attached calculations for culvert sizing. I I I I I I I I I I I I I I I I I I I CHANNEL DESIGN AND ANALYSIS The proposed trapezoidal grass lined channel within this project was sized lIsing King's Handbook (Ref. 3), Table 7-11. For trapezoidal channels: K' = Qn/lbA (8/3)s"(1I2)J where K' = Discharge Factor Q = Runoff Discharge (cfs) n = Manning's Coefficient b = Channel Bottom Width (ft) s = Channel Slope (ft/ft) Natural, vegetated lined channels are capable of withstanding erosion for velocities up to 5 fps. DETENTION BASIN DESIGN AND ANALYSIS: The proposed, localized, on-site detention facilities were sized utilizing the single,- hydrograph method. See the attached calculations for the design procedures utilized with the single-hydrograph method. The detention facilities for site have been designed to account for the increase in flow from the site. Basin EI & Fl were sized to account for no detentions. The two on-site basins join via 18" storm drain pipes. The combination of the flows for the site does not exceed the pre-developed flows. All detention basins are -located and designed to provide a safe emergency overflow without flooding the proposed buildings or causing damage to the on-site grading or improvements by discharging into the proposed 'f catch basin. RESULTS AND CONCLUSIONS The proposed site discharges a total of 32.0 efs. The existing site discharge 18.5 efs. Therefore, the site design includes detention facilities to limit the total runoff to 18.5 efs. The outflow from each detention basin was: Detention Basin 1 = 2.3 cfs, Detention Basin 2 = 1.4 cfs, Detention Basin 3 = 11.0 cfs. Detention Basin 1 is required to have storage volume of . 4131 cf and 4160 cf is provided, Detention Basin 2 is required to have storage vol ume of 1769 cf and 1837 cf is provided, Detention Basin 3 is required to have storage vol ume of 2062 cf and 2130 cf is provided. A Storm Water Management Plan will be prepared separately to discuss the impacts the proposed development will have on the storm water quality. The detention basins are physically designed to allow for emergency overflow without flooding any adjacent on-site building. etentlOn astn DB' S ummary BASlN NO. Q before Detain Q to Detained Q after Oetai n, Detention Basin 1 6.0 cfs 3.7 cfs 2.3. cfs Detention Basin 2 4.3 cfs 2.9 efs 1.4 cfs Detention Basin 3 17.9 cfs 6.9 efs 11.0 cIs TOTAL 28.2 cfs 13.5 cfs 14.7 cfs I I I I I .' ... I' . I I I! I I I I '; , I·····~· .: .. I I, I I II II , 1 , '" l' ... ... . . .. -. . ..... . ..~ " I : " ...... ~ .. - _ ..... " f : ". . ~~~~~,~ ~ . . ~/II/-.r. S?7~oo 1--. : . . ~ .",. 'r'~ ... f' ...... , .. " . ,-.. , . I . ! :. ! i' .f .~ I , I· .... .. /~~ Z/' /,1 OJ" I : " , . 5' 77£ 00 . .. . ... " ......... , ..... : .. , .... , ........ " 4-.~ . ... r IG~I~(~fL ~~ ~:~f;/~r); toi(o;''i;l-)Lid ~;::; ..... :-: · . . ~ J '" / 7 5"-. :: ..... -.. ~-..... -:".-.... ~ ., -r "" .... "'" ... _ .. -.. " ..... -...... .. '"~ ; i . . ~. I I ·~""·· " .: ".; . 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'~~}c/~~ ~.IIE 7-~. ~ ... "" O.~3~: .1t=C .. /l..;: {O,33?J)(tJ?:= {),33,S1 . . //,= aI. ~ /,¥~5 /~I y, ~ .s I !' . 1,./,2. f? F!5. . . : TIM. L //'1 ;z...e.~·eH':;. 7~2-/f/zP~s ~ 7;'0 MI~;"".J ~ -HfOROLUGYSUMMARY'.i - - - - - - ----.-.-.-.-. , ------- Travel Time in Culvert i~asin Area C L So Ti Ii Qi 5 n b K' D/b D Ca Area V L Tt Tc I ,Qf Remarks ~ No. (ac) (fl) (ft\n) (min) (in/hr) (cfs) (%) (flirt) (ft) (ft/ft) (ft) (ft/ft) (sf) (rt/sec (ft) (min) (min) .(in/hr) (cfs) IOO-yr enDt Existing EI 9,97 0.65 1050 2.10 20.5 2.86 18.5 Proposed AI 0,49 0.65 170 1.00 10.6 4.39 1.4 I 0.013 1.00 0.1818 0.44 0.44 0.3328 0.33 4.20 60 0.24 10.80 4.33 1.4 A2 1.27 0.58 700 1.00 2~.8 2.53 1.9 I 0.013 1.00 0.2427 0.69 0.69 0.5780 0.58 3.23 61 0.31 25.08 2.51 1.9 conf 25.08 2.7 BI 1.02 0.85 370 1.00 8.7 4.99 4.3 6.30 6.11 5.3 conf I 6.0 Draining into detention basin DB I CI 1.23 0.85 560 0.75 11.7 4.11 4.3 11.70 4.3 Draining into detention basin DB2 01 3.4~_ ~~5 I 5.?0 1.00 10.9 4.30 12.6 10.90 4.30 12.6 D2 0.60 0.85 325 0.50 10.2 4.49 2.3 10.20 4.49 2.3 conr 10.90 4.30 15.7 OJ 0.23 O·Z~ JQO 0.50 9.1 4.85 0.8 9.10 4.85 0.8 04 0.26 0.75 155 5.00 5.0 7.11 1.4 9.10 4.85 1.4 conf 10.90 17.9 Draining into detention basin DB3 i EI 0.02 0.85 50 5.00 5.0 7.11 0.1 0.1 , FI 1.27 0.85 975 0.50 17.7 3.15 3.4 3.4 I TOTAL 32 ,Developed site 9100 , cfs to detain 13.5 Mitigation 0'100 1 I I I 577-sd.xls Page 1 -- - --, -, --HYDROLOGY AND HYDRAULIC CALCS £~~.!!:~u~:eEAI "C" . CA . Su.~~l~.<ft) S(%) Ti Tt Point Basin Ac. CA I(Ovrlnd (fg) (min)!(min) Flows to OBI i i AI 0,49j 0.65 0.32 0.32 170 1.00 10.6 0.0 I A2 1.27: 0.58 0.74 1.06 700 1.00 24.8 0.0 BI 1.02j 0.85 0.87 1.92 370 1.00 8.7 0.0 Flows to DB2 , CI 1.23 0.85 1.05 1.05 560 0.75 11.7 0.0 Flows to DB3 I 01 3.44 0.85 2.92 2.92 590 1.00 10.9 0.0 I 02 0.8510.85 0.72 0.72 325 0.50 10.2 0.0 Flow from DB) I I OBI i Flow from DBl I DB2 i , I I ! . Flow from DBl i iDB3 ! i EI 0.27i 0.85 0.23 0.23 170 1.00 5.9 0.0 I FI 1.2710.85 1.08 1.08 975 0.50 17.7 ,0.0 I , I 517-sd.xls ---. --. -.. -----.-----11/30/2005 Tc I Q L (ft) S(%) Dia. K' D\d Ca V I Pipe Sizing I NOTES min. in/hr cfs (Pipe) (Pipe) (in) (rps) ; 100 -yr event , I 10.6 4.38 1.4 140.00 0.50 10 0.417 0.75 0.63 3.2 10" pipe I . IT 24.8 2.53 2.7 740.00 0.50 12 0.491 0.89 0.74 3.6 12" pipe 2, ! . 8.7 4.98 4.3 ! I , I I 11.7 4.11 4.3 25.00 1.00 18 0.190 0.45 0.34 5.6 18" pipe 4 , , i 10.9 4.30 12.6 60.00 1.50 18 0.453 O.SO 0.74 7.6 18" pipe 6 10.2 4.49 3.2 105.00 2.00 IS 0.101 0.32 0.22 6.7 IS" pipe 51' 15.7 105.00 2.00 18 0.489 0.89 0.74 9.5 18" pipe 5 I I I I I 0.8 160.00 1.00 18 0.035 0.19 0.10 3,4 IS" pipe 3 i I , , ! 2.6 110.00 1.00 18 0.115 0.34 0.24 4.9 IS" pipe 7 , I 11.,0 50.00 l.00 24 0.225 0.49 O . .3S 7.2 24" pi~e 8 I 5.9 6.39 0.1 75.00 1.00 24 0.002 0.05 0.15 0.2 44" pi~e 9 15.0 75.00 1.00 24 0.30S 0.60 0,49 , 7.6 24" pipe 9 ,'j 17.7 3.1~ 3.4 700.00 0.50 18 0.212 0.48 0.37 4.1 . 18" pipe JO I I I 'I i 1, Paae2 ----------.-------.-.-.-. INLET SUMMARY Q STRUCT. Inlet Gutter Flow "A" Inlet F' Catch Basin Inlet Remarks (cfs) Inlet Type Slope Depth Length # of opening required Grate per city standard.50-yr event (Open) 0.8 I F' Catch 6asin ----I -Sump rnlet 4.3 2 B-Inlet 2.22 0.325 0.33 3.26. --On-grade 1.0 ... F' Catch Basin ----I Sump Inlet .) - 3.2 4 G-Inlet 0.50 0.375 - --GI Sump-Inlet i I 12.6 5 B-Inlet 1.50 0.450 0.33 7.00 --Sump Inlet : 12.0 6 F' Catch Basin --- -2 -Sump Inlet 1.5 7 B-Inlet 5.00 0.225 0.33 0.89 --On-grade . B-Inlet in sump 1.8 cfs per linear foot of opening I G-Inlet in sump . .G1 grate per citystandard with W = 3'-4" and L = 1'-11" --------------"--_._._., i =fT~ Tim~ and D~~~~arge values were obtained using County of San Diego Rational Method Hydrograph software prepared by Rick Engineering Company copyright 2001. Detention Basin #1 Detention Basin #2 Detention Basin #3 TIME DISCHARGE TIME DISCHARGE TIME DISCHARGE TIME DISCHARGE TIME DISCHARGE 0 0 0 0 312 0.3 0 0 286 1.3 25 0.3 12 0.2 324 0.2 11 0.6 297 1.1 50 I 0.4 24 0.2 336 0.2 22 0.6 308 0.9 75 i 0.4 36 0.2 348 0.2 33 0.6 319 0.8 100 I 0.4 48 0.2 360 0.2 44 0.6 330 0.8 I 125 0.5 60 0.2 372 0 55 0.7 341 ~~ 150 I 0.6 72 0.2 66 0.7 352 175 0.7 84 0.2 77 0.7 363 0.6 200 1 96 0.2 88 0.7 374 0 225 ; 2 108 0.2 99 0.8 1-~ .... 6 120 0.2 110 0.8 250 275 0.8 132 0.3 121 0.9 300 0.5 144 0.3 132 0.9 325 0.4 156 0.3 143 1 I 350 0.3 168 0.3 154 1 --375 0 190 0.4 165 1.1 192 0.4 176 1.2 204 0.5 187 1.4 216 0.6 198 1.5 228 0.8 209 1.8 240 1.1 220 2.1 252 4.3 231 3.1 ! 264 0.7 242 4.9 276 0.4 253 17.9 288 0.4 264 2.5 , 306 0.3 275 1.6 ; I I ---..,.:-.. -.... ~ --,JI!!!!!!J "l"~, rJ (;(~1 ,~-" ( /, " 5, Ci)4 LL ~ ;: o ..J 3 LL , ~~; r. / ~ 1::-" ,..' ,f ,~': .-:~, . " _,,_~ __ ., 'i4('-, 'j ," .-l o .-----" o .~) i:" e1;~!' /".; ~' .. 25 50 75 100 • ,'. -. ,f.;" ./. 0':'/ " UI/] ,h-r' ', .. ~ 'J.; i'f ! ' ~. /f i . r h .. ) to-it; .-.-... . - DETENTION BASIN #1 HYDROGRAPH 125 ""'lrl":l/r~!) ," ~.,~; i .. ,..;. 150 175 200 TIME (MIN) >- 225 ( / ,r':-' I) ( q?, ~'!~; /-1 :.:::: (t::· f-" -,~,~~,:;) (I.r.;; c r.~) ~:":/~1" \ ' .. "t. f' J J!! i f, ,.i ! /_ _ 1/ J --:? ) .,~. V ~r-'''' _' ,! / ~. , .. ,/ .J./' ,. -ti' . I /,!,-i..~.:' , :::> . . _ .... /. . ----... ~. ' .------- !"':': :: ,,-; 250 275 300 325 350 375 .. . - OtJ{f -. ~ / ~t1.,C '.r' .: " .. ' ~; -,.. '': :. , .. ":. . --... .. ,-.. .- -: .-.. ,-.. DETENTION BASIN #2 HYDROGRAPH - - - - - - ',;'~ .N;.:':,:'; ',' :~ : _:~ • ::. ;;-;· ... L ... :;: . ... ,~:?:!:.:~ " " '. , . Ii III'·~· :/i 7 _ I( ! (,,:> 1 [.·f~ ":; ~. .o( ", ,,: 1'\ J- o ~ .... '" ~ ~IO ~~~~~~~~~~~~~~~~~~~~~.~~~~~~~ ~ .... ~.... ~ ~ ~ ~ ~ ~ I), I),V ~ ~ ~ '" ~ ~ ~ ~v ~ ~ ~ ~ C' -r'.;.,., I :, i _> ,' .. :. r • -.. '"l!~ . , ;/~:~t'.~! /.// ... -." .-{API., -"'.1 : i ·,.l u .,.. ". "-;, r. t.. ..... ',; i ,S . ! t, :,' ,11 .,J (.. 1'/;;" __ \ I . ,f I. " •• 1.1 .. "\. I ( ') (/ ,-; '{ \ lJ.," '1' ,.' .... ! :/~J ~;' ,j'·i,'J ":' 'I! I! /./ .} • ..., • ..,.,'-!. ~-'~ .. ,l .. _ ~':!,~Cj,-·":/l.'_' ... ' ;:~ TIME (MIN) r: ,. ",'. ," :..'i! t .. r, \,'L) /) }~?/CI -Co U 'P/:.:1 -; f r'b I Cr , .. -" ,-.. , .... . .. -_.". ........... // .. - -'I . " I I 5 I , I \ • I ~ ~ I! 11 I II It , II r I I I 1\ f M ~ ~:I: fJ)1l. « ma:: Z,e> 00 -a:: 1-0 Z)-~:I: W C o C'\I ! " ":,, .. '::~. :,.:'~';: .. :'. I "'':'':'' co .... ':, " . '.; ." ~ \",' :! . /' / " vi' N ..... 'I",,'" r,,' • o .... .. ,': .. ', -':1'" .). \',,::': "','.} .!':-'; .. <0 ,.: . " ,', L ~ ---..... r-r----- .... ~ ::. : N o ~C" C",9, C' ~ i!' "JS C' OC) C' 6} C" c90C" <e~ 19<2 ~ ..9<~ ~~ C'$I~ ~.,s~ ,,~ ~ 0c? 6'~ c9~ 'L <0} 19~ ..9,9 'L JS~ 'L C'.,s J! ~(I ~ ,,~ ~ 0" ~ 6'6' c9c9 « 1919 ..9..,>1 JS-s (1(1 ~~, "" 0 ~'~t. \,j'; ,.,. \ I 1,,\ .\~ i \ ~ ; ~ ~ \ i..c. .. II :: -~ '\~ .~ Z ~\{ ki; ~ ~ ......... l..i. -~ w ':::'\ ~ ,., i= ",~ . /,., ~. 1\ ...... , ....... ..... , .... '} ..... '" .. , -~. \,.; ....... ~. "';. ..... ~ " I ~, ...... ;;:.. ..... , ~ ., "';;- . .,;." ""' ..... ... .~. =i. '!'\ ~ \:) -.....; '_.r ' . : .. .., ~~.~ , .. .. ,' , "'i '. ' I" " ( " =' .. : _.J " I .:.:~ ,~.- ""'-.../ ...... ............. '-, , " f'·, ~--... "'=':-'v ." ....... , ,~: i (21 (. '-" , ...... ) \ '-.. ... II \Jl'\ I \ I I I I I I I I I I I I I I I I I I I Bressi Ranch Lot 40, Carlsbad California Hydraulic Analysis of detention basin outlet structures DETENTION BASIN 1 ORIFICE EQUATION Weir Formula for Orifices and Short Tubes (free & submerged) where or Q = Ca(2glr/12 Q = the flow rate, fe/sec C = the orifice coefficient of discharge a = the open area of the orifice g = the acceleration due to gravity ........ --_ ..... "'-. , .. h = head on the horizontal centerline of the orifice Q = Ca(2*32.2)h/12 Q = Ca(64.411/12 ; C = 0.6 Q = 4. 812a(Ir/12 " = /QI(4.812a)! Detention Basin Calc Given: Q=2.3 eft y= 1. 6ft. where Y is the height of the water Assume: a = 0.3491 sq. ft for a 8" diameter pipe Then: Ir = 104ft Y=1.6 ft Check: Is 11=1.4 ft < Y= 1.6ft YES --- y , I I I , , .. -I f I • I t ~ II Ii • II 1.1 II i II I Bressi Ranch Lot 40, Carlsbad California Hydraulic Analysis of detention basin outlet structures DETENTION BASIN 2 ORIFICE EQUATION Weir Formula for Orifices and Short Tubes (free & submerged) . Q = Ca(2glt),12 where or Q = the flow rate, fe/sec C = the orifice coefficient of discharge a = the open area of the orifice g = the acceleration due to gravity' ........ ~., .... -............ . h = head on the horizontal centerline of the orifice Q = Ca(2*32.2)J,),12 Q = Ca(64.4lti/2; C = 0.6 Q = 4. 812a(II/12 " = [QI(4.812a)j Detention Basin Calc Given: Q = 1.4 cfs Y=1.9ft· where Y is the height of the water Assume: a = 0.1963 sq.ftfor a 6" diameter pipe Then: /, =2.2fi Y=1.9ft Check: Is /, =2.2 ft < Y= 1.9/1 NO Assume: a = 0.3491 sq./t.for a 8" diameter pipe Then: /, = 0.7 ft Y=1.9ft Check: Is II = O. 7ft < Y = 1.9 fl YES -- h y 1\ .~ I) II It II· . I I I I I I I I I I I I I I Bressi Ranch Lot 40, Carlsbad California Hydraulic Analysis of detention basin outlet structures DETENT10N BASIN 3 ORIFICE EQUATION Weir Formula for Orifices and Short Tubes (free & submerged) where or Q = Ca(2glt)'11 Q = the flow rate, fe/sec C = the orifice coefficient of discharge a = the open area of the orifice g = the acceleration due to gravity· ...... --" . -......... -....... - h = head on the horizontal centerline of the orifice Q = Ca(2*32.2)lti12 Q = Ca(64.41t//2; C = 0.6 Q = 4. 812a(II/12 II = [QI(4.812a)! Detention Basin Calc . Given: Q = 11.0 cjs y= 1. 75ft. where Y is the height of the water Assume: Then: Check: a = O. 7854 sq. ft for a 12" diameter pipe " = 8.5ft Y=J.75ft Is It =8.5[t< Y=I.75ft NO Assume: Then: Check: a = 1.5708 sq. ft. for a 2-12" diameter pipes " = 1.5ft Y=J. 75ft Is" = 1.5fl < Y= 1. 75ft YES h Y I I I I I I I I I II' II. I II II II II II II II II Therefore use the following: Detention Basin 1 : use 1 -8" diameter pipe Detention Basin 2 : use 1 -8" diameter pipe Detention Basin 3 : use 2 -12" diameter pipes I I I I I I I I I I I Ii i 11 It £ Ii I Bressi Ranch Lot 40, Carlsbad California Down Time of detention basin flow outlet DETENTION BASIN 1 TIME DISCHARGE EQUATION where T=VIQ T = time duration of discharge in seconds V = volume of detained water ft3 Q = the flow rate, ft3/sec Detention Basin Calc. Given: Then: V-4131 cf Q =2.3 cfs. T= 4131 if/l.3 cis T= 1796 sec ~ T=29.9 min Check: Is T = 29.9 min < T ma.'!: =4320 min (72hrs) YES DETENTION BASIN 2 TIME DISCHARGE EQUATION where T=VIQ T = time duration of discharge in seconds V = volume of detained water ft3 Q = the flow rate, ft3/sec Detention Basin Calc. Given: Then: V =1769 cf Q = 1.4cfs. T= 1769 cf/l.4 cjs T= 1263.6 sec ~ T=)1.1 min Check: Is T = 21.1 min < Tnllu: =4320 min (72hrs) YES I I I I I I I I I I I I I I I I I I I DETENTION BASIN 3 TIME DISCHARGE EQUATION T=VIQ where T = time duration of discharge in seconds V = volume of detained water ft3 Q = the flow rate, ft3/sec Detention Basin Calc. Given: . Then: V=2062cj Q = 11.0 cjs. T= 2062 cjlll.O cIs T=187.5 sec ~ T=J.l mill Check: Is T = 1./ min < TmllX =4320 mill (72I"s) YES I I I I I I I I I I I II II 1/ If Il II j 11 I; i I ! i { • f I ! j ( t t : . I : '. ': I II ~ ~1. [>('" , ' ... " . \, .. \ ' .. ... , , . '. j j j j j j j j j j j ,j !j j j j j j j j j j j j j j j j j j j j j j j j j j j j j j i I I I I I I I I I I I I II It II Ii II II APPENDIX ---~~&_-----.--~~~~~ ~ ..-..- San Diego County Hydrology Manual Date: June 2003 Table 3-1 Section: Page: RUNOFF COEFFICIENTS FOR URBAN AREAS Land Use Runoff Coefficient .. c' Soil Tl':[!e NRCS Elements Coun Elements %IMPER. A B' Undisturbed Natural Terrain (Natural) Pennanent Open Space O· 0.20 0.25 Low Density Residential (LOR) Residential, 1.0 DU/A orless iJ";'. -... ' , 10 0.27 0.32 Low Density Residential (LOR) Residential, 2.0 DU/A or less ;J,I, ... ' . ..: 20 0.34 0.38 Low Density Residential (LOR) Residential, 2.9 DUiA or less !;~ : ... ., 25 0.38 0.41 Medium Density Residential (MDR) Residential, 4.3 DU/A or less IOlt .. tl:'4.. 30 0.41 0.45 Medium Density Residential (MDR) Residential, 7.3 DU/A or less 6·"":,1/ 40 0.48 0.51 Medium Density Residential (MDR) Residential, 10.9 DU/A or less If: ,"" :.[ 45 0.52 0..54 Medium Density Residential (MDR) Residential, 14.5 DUiA or less . . , 50 0.55 0.58 .. -. ~ .... High Density Residential (HDR) Residential, 24.0 DU/A or less 65 0.66 0.67 High Density Residential (HDR) Residential, 43.0 DU/A or less 80 0.76 0.77 Commercial/Industrial (N. Com) Neighborhood Commercial 80 0.76 0.77 CommercialIIndustrial (G. Com) General Commercial 8S 0.80 0.80 CommerciaVIndustrial (O:P. Com) Office ProfessionaVCommercial 90 0.83 0.84 CommerciaVIndustrial (Limited I.) Limited Industrial 90 0.83 0.84 Commercialnndustrial (General I.) General Industrial 95 ,0.87 0.87 C 0.30 0.36 0.42 0.45 0.48 0.54 0..57 0.60 0.69 0.78 0.78 0.81 0.84 0.84 0..87 3 60f26 D 0.35 0.41 0.46 0.49 0.52 0.57 0.60 0.63 0.71 0.79 0.79 0.82 0.85 0.85 .0.87 ·The values associated with 0% impervious may be used for direct calculation of the runoff coefficient as descnbed in Section 3.1.2 (representing the. pervious runoff coefficient, Cp, for the soil type), or for areas tbat will remain undisturbed in perpetuity. Justification must be given thall"e area will remain natural forever (e.g., the area is located in Cleveland National Forest). . DUiA = dwelling units per acre NRCS = National Resources Conservation Service 3-6 I I I I I I I I I I I I I I I I I I I i I I I I I I I I I I I I I I· • ~""~I' ...... E ~ .. ! ! .5 II = .. II .;. g - I } ................ _. "''''' -:-.. -r--:lt ... ~::::-... -\ ""'~:;(:.\~. r""" .. "".":;. -;::·-: .. ;:r'''''fJ~a~ii'''<n-:-:--;-j-:=t:i~~~5:::::;:;';;;~::'';:'~;:&Oiiliioll;''';;i:::::';;;'''':''----''''''---t ,~~alU .1..:.' l..:::'::';~'<~:.~: .. ~ .. ~. j::"'..... ".,'" . • U'~ •••• .. 'I,. .i',. ...... ..•. . ......... .. .. ' " • , ••• : 10 ' i .. ~" .... •. • .... J. . ¢! • .. ' ~ ~ ,OC.l~~ --tj=::--\"'~:'--::ii~F' --+----+=:::::--\;---+---------4------------4 «.llL ~ · .. :···l+:~·2.: f. .. In ~ ... ; k. _. f:! ..... _ .. ... .. ...... ... -" .. ~ -.. .... -.----... ~ .. .. .. -' -- ~, J! {~~ b. M , , in f • ~ ~ ~. ;:., , i ! :: ! i; .. 33 • Crane ,:' ,.'; ;i!; d ' :11 iIi!··:!' ,.-,/./1 '1'1;:1-!-'I-'/f"I"JI-j'~ , .: .• ' I , .. J • I '!! ~ : County . ='" :o.ti~. . . , i ' , ' : : :; i; I " ! : ;" I: 'j II! i 1'1 1 i '. /.:' jif!rJ : I I I l If! 'j . !: I I I " ". i' : i !.,: ; I ':: '. ;t;. • • ....... 33't~~~~~_~ -1), : pri1>r&O ~5irc: .' !: . .~., ., (l 33°W' .. -:;. . ,(l I ' :;> . ,0 C'I ~ ~ ? , . N ~ .. ;~ .. .. ! 32""5"~J-~~~~~~~~a~~~~~~rnJliE0J • i f ! . I I . ' . . j ; • . , , ; : I : ,'. ' '-"" I I ; '32'30' . ; i ! i ' ! ' (, I' . 1"-' ~ 1-1 I I I Ml t: ~"', "" I I' 1--' t-·· .'1 / • . ,... , Ii i! II f!' .. _ ;.t! .. , i .! j'l! i I I I " ,~. ..: in .:,!' .. I ,/.1 'IiI tt·;-f.':'j --II 'i I f :1; : !:: :-; . !", ;; i3 [ 1 Ii I II I'U" j' J J / in I 1./' ; I" i 1 :. I'!!:: 1, -...., ,I .•.• !, ! " ' . ,_. ,--•.. ,. ,,.. , , .' ' , l .:: t : : I : i .- County of San Dieg< Hydrology Ma~ual • Rainfall [sop{uvia[s toO Yen Rainfall Event -24 Houn IsopIuvi3I [1Ildles) DPW ~GIS -.....-..,.--~--- ~ SiiiGIS 'A'='t.r. • .::.'i.Allr. .. ,C .... PIe N ... _ .......... .".",......wIiIftYVlwr .. .,.,.. ..... f CIIU\ilD..o.~ ... .", .. ruto MM\.U • ....."... DI .. ~_Ift""O',,.,. ...... ~~ ! ~~-...... -.......................................... E -..---.. -----. _____ fII~ • .......... ------......... ---......... --...... s 3 o 3 Miles -- ~ ... ,-. -. -.... - -.... -............ -., .... ", -..... -' . f ;-b .., r.. ,:: I I : i j i!. : I . I . jt t t J f f I f-ij:I: r l-' : .' '''' ..' ' ! : I It .. , i ! '/" I I I I;:! I ' . . . . ,;,~..' .. ." , . I ' . r ' , . .: .6 '<6~ , ";'. ;! ,i " !! : , ' t, . IV I " .. , , I'! " " " ; .. i" 33.,5' :-;l !! ! 1/, {f' ,~P~c/T i:>(TE: " ": '~fP~r 1",; '" " " -:;;. ':j: ~~ .~I . . : ... ~. .,. ' . '. ,., - ; t 33·00" (') SOlAII&A w:ar : ':i).: <:,: .. .. !"() '0} • ! ; ..... , '. ,~ 't .... o (l ,I I, . (Q'! j Ol ; ; ':): : ; I' ' . , t· •. '. ..... :. ,.,,-."-" " I' ~ , '~I~' ;\. ... t I •• :'lr' ... It. • ~ .. 1 i, l. .-,,' .; .. ':.:: .; 2·.c~; "ii. ."."'" 'f ! ; I I i r ! , I : i . i . ~ r; •. . i ! J • • • • • • -, • u..-.--:-----; i 32'30' ' : ,::; li I ~'I' I· Ii,' ,,' 1"11 t:: ~; 'I' ,\I! i /' I!' t I '1'1 ! /' I ' ' , " " ., ,I IV , !" ' t 'I 'I I , . ' , .0 ' " ; , :' 1, ,'" l '., I I j " " .. " .• 1'r'·'·' ./. . , , " . . . . . . ; ,"'" : .. ",'. '.' . . '.,-.. " " ~ .•. ' ... f:' , ;" 'i 'I..' , i II . I; • I"" i ,i I'" " II , I ./1 ' ! -' , " "';: ; i ' " ,; ":. I I .,..,.' , ' I' • I ~, ' I , •• ! I.' County of San Dieg< Hydrology Manual Rainfallisopluvials 10 Ytar Rainfall Evrnt -6 Hours I50pIuvUI (inche$) DPW --6GIS ~ . s1ilGIS. .......... ",........, ~---... \a.i:J"" .. :...n.l~ .. ' ... ~ N :'-:':=-:"'~1':=:'«t...,-=~ f G~",--,-"'_···"M_.""""'_ c.,. ................... --------.. ~ ...... E ____ ~~.,.. .. ,...... ....... a. ~--~ .... ~ ... -......... -... "'----.. ---....... ~ ...... -, S 3 0 3 Miles ~ --------..--'-.---. ... ------", o . ... ~ .... 33 . ~. il d it ,'lill! Ij l' .... !r--/l .. ,t, .. !.-f!·-I'·:;-H Q •• ~ •• ~ ." I, 111 I III 'I' • : . ..... . • • ! '. ' • . ,...,' j'j . I' . ! " " i ,," Iff!, , ,,! ' " ;, i," '; ::, . !' :. ,-,' I ! , • :. .C? .. : .. :.~'. . ;:':' I, ' ! j I .. I 1·\ ,!! I I j I ,! ,I • ... I' ~ ! 33"7TlL~Etfj;z~~tm, i8~~~~~~Jf@gg : l! . ,.. . ::peO~(;~ :. 'Sin> . . ! • 33"00' I ":., .. :' .. .~ .~.:m fP;!T.lj\< ,-+" : ' " " _ ' ~. _ J.-H .; .. . ~ .. 1 ~ • : 't. .. . ,. . ~ ! 32"45' • ; : . ;: '! , .. ~ : f 1": ,;~_ ,,'_ ! rd,-'I',';;' _ ','{ "( --'! . " ' ,~," ,;:, 'J; .:1 8.;' i' /' _ ,. ._ i 1 ,'f !':! 1 ~I"l f ; -_ t • I :;. ·-f! I'f ,I '-, I! ______ 7_ --. __ ~ ....... ' County.of San Dieg( Hydrology Manual <I Rainfall lsopluvials 10 Yelr Rainfall Event -24 Houn IsqlIwiaI (inches) DPW -gGIS ~ S~GIS ~.,.,,-~-. .,.-.-\l,\: tt. •• :-11wpo(a.u..-a: N ,.. ...... ......",.....IJCIIn ............... CII,."_,,,.... ...... * c.-.ulOQ ........ an.,'~'VSto~~ .. • ......... CI' ... .IIIC...-r .... '"_', .... ___ a~ ....... , ~..-...... ---' "-..... _----.-. ...... E .....-..-. ... ~ .. ,..... ....... . _...-.,.......-:a S ........... ----_ .............. ....-.-.... -----...... 3 0 3 Miles l"'"Q --,----' ....... _ . ------: ;: . ..., , 'J::':~:;;; : ij ~p. l'r T I I"" ,. , . , ! 33' '; i" ; I , ::; , ,i i i . ! if· II . 1 !... ; f I I iii '1 ;: 1 • --I · . , I • • , • • II I" I j I! 1/ " 1 I I f • I :' ••••• c..... . • ii' I ,I···· I· I " I .• ' . ,.~. 5 '. .' • . , I ' I " ' 1 1 I I . , ___ ~ .... ~. ,!.' . j ! I 1 ..... 1 ! 1 i I • ," • ... • . :! ,., . I. I 1 : . ~. ~ , , I' .1 I ~1:~ 33"~"-~' _.L.·i' . ···T-: . , ''n:; 'I Ii r·' .• ·· I 'L~ n';i } : 'ffjOJeC-,! 'I . f! "II .. ~ .. !iii 1/ . rJ. ! .. I t .... 1 .""". ,. ,,-,.-.----0 1 • , ' ' ,. Ie-, •. " : . .' .. 0'1 . ..r",'" i " •. p" . EfCM._, -:; •• : 1 • f : .. ' . "'00' P __ ",'0 :" I .. : .• p' ........ ,' (II. ~. .. 0'1' , ,?; ... , ". I . . ,'~ , II " .. -., .. , , . ::" , r ! 32.45' ""'-r~' ! l :; ; 1 :i-i' T.i"·!; !": I I! ~.!: ~. f·O .••• ~ I;: t .... : :.. .. !.~ .:~~. : t i "-_ '.~-~: .... -... f· ~ . , ~ ! ~ ..;., i' ;' ,.j ! . ' I ,; . :;1'32.3(1' '1,>'; .:: ;':!i' ·iliT-l·,I.j i'ILlj" HVl!el7\lli~ ;1' ,"It 'I' I : :. .,. 0 . . . : I . J .! .,-,'" ,'I I j ·1·1..1 '. i' /11' I. I !! J.,'" .. .., .' , ,.' I. ' J i' , : ' ,; ~. ' i:: ,;: . il!' ii~li If,I .... lj.; j !tJ11. .. l!iL ,! i ~ii ',;: II! . ~ .:: ! . i . !, :! rEo i ./ .-: -, . -_. County of San Diegc Hydrology Manual • Rain/all Isopluvials 1 Year Rainfall Event -24 Hours Isop/uvial [WICbes) DPW *GIS ~ . S1i1GIS -",--... ~-.".---_·c.",.:\M1Ilk. ... (:a .. ""~ . N tHII.., • ......a~ • ......n • ., .. .",. ..... f OtM'lIlDIQ~anlCll1M'l.DIDfHl ..... U.~ OI .. ~ .... trY...e.,t ... ,.. .... fOA.M..-oIIL c-,."......-...... -................. -... -......-..... E ~-.-.--.. -----.......... ~ "'-..-.... -_ .......... ....--~,... .. "'--..... .... s . 3 0 3 Miles ~ -----. -----.-. -. -.. -~ ._" -" -. -.. -'0. , e "!. 5. 5. <t. 3. 2. ~ :J o E :l L: ,5 •. ~o. ·~o. ! , .so. . ~ o. . . .:-' O. .. , ' .. t ~ .' :'1 " o. o. 0 .. o. 0""" " "-~ ~ ~~ ~ " N r-.. t--. ~ " ~ r.J ~ I i ~ ..... .~ t.....: 'I ~ ~~ ) r-... 'I' ~ "-po... ) I ~~ I' t'. !' " 1 ~ , t--. I K i i i I o I ! i g i ; 8 i r ' i I i , 5 I : 5 I ! , i • . , J. i I , 1 -. . '-. ----.- 2 ; -+- 0'_ ->-. -f--;- T --,. + 1 ~ 6 ya910 "'" II " I " t-~ I ~ , .. ~,..~ ~ I , i ~ I" ~ I I .. r-.. ~ ~ i" I"-~ ~~, i' r-.. ; r.;.1""i'-. r-. t'-o ~ i ,,,' .. ~ ~ ~ ~,~ " '" "'" ! ~ H.. . , .. '" I"-: I l t'-t--.. ~ U. ~t--. "-, .. " t"-..... ~I.f' ~ " I I~' ' .... { I j. " '" o I II~, ~ r... I I ! ' ! " i'" I !. ! I" ,i i ! ~ i~' l =1:': : . 1-= . f- 1-. 1-' I '~ t::: 1-"-f-l-. --. . l-..,. I- . O!.... . I -. ~-1-l' 1- f-' -0 ; I-0 . ,- j .-. -f-0._ 1 15 20 ~c 40 50 Mhur.es OUfalion ! I : , , f : : , . ! I i i I EQUATION , I = 7.44 P6 0-0·645 I I = Intensity (in!IV' I Ps = 6-HourPreclpiiation (in; j I I 0 = Duration (min) . i I r i I ! I ~r-.: ~ i ! ~I' 1'-1; t'... I ,",,' : !l'" R I '""~ "'"" ; I ;, , I , '''-~ ~ ~" 1 I I " ;, I ! ~ "","':0., ! IK ~ ~~ :, ! I ! , I" ~" ! "'-"-,,-" 0 ; K. " i I r;;;: " , ...... " : i 1, ~ "'t--' I i I . ........ ~~ I i" , I ...... ; I ~ ~" f'.... i ' I I I-•• 0 o ~ -I~ . l -. , 0 .. . Ioi: -: , o e-o i , : , , : . 'j . .--t--. -. .~ -. ; I 0 , .1--0 • , --. : -: ; , 1 I , j 2 3 .; Hours 5 6 y. if 5i ." $ n eO '2: !5 ~ 50 g C5~ 40 g. m 35 ~ :!o :a a H 10 'ntenslty-Duratlon Dee'gn Chart· Templat. DInctJoI1l tor Applcallon: (1) FrOOl precipitation map$ detefr.1ille G tv and 24 hr amounts tor the se,ec:ted rrequency. lhese maps are induded in the County Hydra:JQY Miftlal (10.50, and 100 yr maps idJded illtle Design and Procedllre Manual). (2) AdjuSI6 tv precipitation (if ~cessary} so t/\at it is Y/ilhin the range of 45·k to 65'Y. of tta 24 hr precipitation (oot applicaple iD Desert). (3) Plot 6 hr precipitation 011 the right side of !he chart. (4) Draw a line through Ina point parallel 110 the plotted lines. (5. This line is 1he iniensiCy-duFation cur-e for the kK:ation being ar.alyzed. Application Form: , {a, Selected frequet1cv /110 year (b) Ps = ~n .. P24 = f,,5',~ = ~ ¥;ici P24 - (c) Adjusted P6(2J = 1.,? in. (d)'x = _ min. (e) I = _ in.:hr Note: This chan replaces Ihelntensily-OLWation-Fmquency curver. used since 1965. PS • : 1.5 2 2.5: J 15 4 .... 5 • 5.1 • Dur&:.m I . I 1 I' II! I I I I : ..... 5 2.63 3.9S :.21 65~ 7.50 922 10.504 11 ; 1311 'U91!!81 : ..... 1,2.12 '3.18' 4:24' 5.3:'G.SO· 7.42! ..... " 9.~ "0 . .;0 1t,Ef; '2 n 10 1.66 "2.53~3.31'· 4.21·5.0,0"5.lIO: 6.74: 7.M· •. 42 I,ill 10 II . 15 I.la :'.95'2.58 32,'3.119 ... s.: 5.'." 5.~' •. 49' T,I:! 17. ~ .. 20 1.06:I.62·2.IS'Z.89·3233.77· ... 31'·,U!i·S.:;9 Si! •• :U 0,93' 1.40' 187 233' 2.110' 3 27: 373 " 423 ••. 61 5 ,:! SIlO" f," ........., • • • , 30 0.83; 124 US 2.01 2.49 2.90. 3.32 3.73 •.• 5 .. ~ .. sa I 40 069 '1.03: 1 . .38 I.ll· 2.07' 2.4'" 2:75 ' 3.1) • 3.43 315 4 '3 500.63 :0.90' '.19 .... ". 1.19' 2 . .s: 2.:» • 2.6~ "2.86 3 ce 351 10 0.!t3 '0 .• ".06 t.33 1.5i· '.16: 2.12' 2.3;' 2.~ 2.u 31e to 0.41 :O.6'·C.82 1.02 1.23".43: i.6J' I.~· 2.04 2."e 2~ 120 0.34 :0.5!!'''.611 C.15 ".02 1.~9' 1.31 " 15): 1.70 ~ 81 2C4 150 0.29 ~0.4"!C.!i9 C.73·088·I.03' 1.11' 1.:12" 1.47 ,.~ 1 ie '10 0..26 :O.39~b.52 C.8S '0.78'0,111,0 f04' I.I!· '.:;1" , .... '157 2~ 022 ;0.3.>"043 C.54 '065'0.76-0.87' OM: U16" 1 tg 'x 300 0.19 f0.28·~.38 (.41.'0.56'0.66" 0.75' 0.e5" 0.94 . '.j~ t 13 »0 0.11 :0.25' j.33 (.42'0.50'0.58' 0.&7" 0.75 . 0,&4 .O.ei t OC FIGURE ~ - ---.--- -----_._'-'_._. -~_ .. " .. _. ~' ~~~~~~~~~----------~ '0. S 8. '-,..., "t-.. "-~ to... ! , ~ DIrKtJo .. tor Applcll'on: "'" f'.... , ~. ~ " .! 1 ~ " ..... l" 1' ..... .... .; ) ,,~ ::> I I i ~ ....... ..... . ..... ) . i'. ~ ~ to.. ... -;. ~ I , I .. ~ ~! I .. ~ ~ ~i'. ~ I' ~ ~ ~~ I I t""--i' K ~ r.... K. Ii ~ ~ i' ~ I ... r. ~ , .:-., ~ ~ ~ I~~ ~ , I .. ~ to.. ~ r.... ; I I'" I ~ ~ ~ 111~ ..... ~ ~ ? 6. 5.0 u 3,0 ,r ..... ~ I I'r--, ~ ..... i ~~ I; : , .", i ~ " I " l-f.!. I i~ K I ! ~ " ~ 2.0 I 1'" ~ ~ I [' ; I i II . I . ! i I~~ ~ i I ..... I ! ! ' II ! I ! ! t'i ; I' I I !" I I , , ! iI ! I ; i I I i i' ! J . . ; Ii. I ; I I I I t , .I i , ; : ! "-' -. , . -. '1-... . f= -~--.: ,= f-. . 'f-- 0.5 u 0.3 t= I-f-. "'1= .: .~ , -i F-: · . 1-I-f-I-~ ·1-"-I-t-. ! .. 0.2 .. , . t .-_. ! -l , 1--+-· .. 1-'-I-I-. --+-· . ,-.~ . --.-'-i-. · . ... '-I-t . -.. .j . ...,. 1-,-' . --. --+-.. -1-. -J I 0.1 l....-....:.... ____ ~ __ ~ ! 6 1 a 910 15 2() ~() 40 50 Mhules Duralion , ! 1 i I ! ! ; ; : I EQUATION ; I I = VI4 Pc 0..0·645 i i I = Intensily (in!nr) I P5 = 6-Hour Precipitation {in; i I ! o = Duration (min; : I I ~ ; I ...:. ! · I · I ! ~ I~ , i ~ ! I ~ Ir;.:: ~ I '" i . . ... t' I'~ ; I ~ ~ r' ~ ~ I I I .... t' : I I ' I I ! I' ~ t'lf'. ~ f'~i"o I i f' I- I ; ~ ,. ~ f' I' 1"000. ~ f' ; ! K f' I ~ ..... ......." I ~ , I , ,,,,, i' f'", t ~ ....... i' I ! I'" 1" I ~ I I f' 1'1' I t ; i , . . , .1" -: t " 1.3100 i --; 1 . -t ! , , ., . --t-. . . -. ... -.. 1 I , ~. r--. '1-. , , -_. : I ! · 1 I . ~-! 2 3 ~ 5 6 Hours 'l' ~ c ., " iii n so '2. 55 ~ ~o g 45'S 40 l 3S~ ~o 25 4.0 u HI fntenslty-Duratfon Des'gn Chart· Template (1)> from J)recilJitalioo maps determine 6 hr and 24 hr amounts lOr Ihe se:ected frequency. These maps are included in the Cc:lunty ~mlogy Manual (10. 50, and 100 yr maps nckJded in ltJe Design and Proced!,,18 Manual •• {2, Atijust 6 hr precipitation (if necessary) so tnat it Is 'hithi'l the range oI4S·A, 10 65". of t~a 24 hr precipitation (not applicapfe iO Desert). {3} Plot 6 hr precipitation on the ri~t side of Ihe chart (". Draw a line through ll\e point parallel ~ the plottac: line6. (5) This line is 1he inlensily-duration cunoe for the location being analyzed, AppllcMlon Form: (a, Selected frequency ~ year (b) P6 = ~in., P24 = I, q .;6 = 0.3 ?,:i~: ;? 24 [e) Mjusted PS(21 = ~ in, (d) Ix = __ min. Ce) I = _ in.:hr. Note: This chart replaces the tntensity-Ouration.f'requency ctJlVesus.ed since 1965. pa '1.5: 2 2.5 I 15' 4 4..5 i 5.1 • .DuIB!ICI'I , ,', I I I I I I 1 . ., 5 2.63 3.95 5.21 E5:1 7.00 sn·lo.SoC I'.~ 1311 ~,Ug'~SI '1 2.12 '3.18' 4.24' 5.3) 6.:;~'-7.42· 8."10 • ,.~ '10.60 'H6 1212 10 1.Ci6 :2.53: :3.3]" UI : 5.::0: 5.110; 6.74 : 7~: '.42 l.c1 1011 15 1.33 '.95 2.58 324 3.89 -4.!>4' 5. t. 5.84 •. 4' 1.':! 111 20 '.011 ".62'.1.15 2.&i·32;f3.77: 4.31' 48S' 5.39 Se! a-te 25 0.93 : •. 40'1.87 2.33' 2.80' 3.27: 3.73' 42')' 4.61 . 5'! 580 30 0.83 :.241.fi6' 20,'249'2.90' 3.32' 3.73' •. '5 '.~ 491 40 0.69' •. 03= '.38 '.72'2.01' 2 .... • 27&' 3n' 345 . 37' 413 50 06() ;0.90".19 ,.-4,' 1.19'2.09= 2.:»' 26i' 2,96' 3~t 3s1 10 0.53 'O.SO·,.06 '.31 1.58".16' 2.12' 2.3~· 2.65' 2.u 311 to 0.4' :0.6~' C.1I2 1.02 1.23 •• 43' tAi3' '.1" . 2.04 Z.c~2-'5 _.' 120 0.34 =0.5' !l.a US '1.(12 I.'g' •. 3&' 1.5)' 1.70 ~ 87 2C4 '. _ 150 O?9 :0,"(9.59. C.73: OM: UC( I. ,.: '.32 : 1.41 , l ~ .. ' 7' 11100.26'0.390.52 C.8S 0780.,. 164 US 1.31 1 ..... '57 . 240 oniu:fc.43 C.S-·06S·0.76·087'09S'I.06'1.1S IX "300 0,!910.28·~.36 ( .• 70.56'0.66' 0.1s· US: 094' ';:)S ! 13 ~ 0.17:0.25'0.33 , .. 42 0.50'0.58'0.67'0.75'0.&4 O.ii H)C._ FIGURJ: ~ 1~1.5·--+1 2% :_------n=.0175 11 1\ I; ~::::::t:::===-~~ __ ~2O/'~o--::==~~ Concrete -~..\\ Paved RESIOENTIAL STREET Gutter ONE sloe ONLY I I ! I I I I I I I I I * i \ I 2 3 4 5 6 7 8 9 10 Discharge (C.F.S.) EXAMPLE: Given: Q. 10 S'" 2.5% i Chart gives: Depth • 0.'. VtlocltY:II ..... f.p .•• SOURCE: San Diego County Department of Special District Services Design Manual , 1 I I- Gutter and Roadway Discharge. Velocity Chart 20 30 40 50 FI(;URE 3-6 I I I I I I I I I I I I . 1\ 1\ t I: 1\ 1\ CHART .1-103.6 A CAPACITY OF CURB OPENING INLETS ASSUMED 2% CROWN. Q = O.7L (A+y)3/2 *A = 0.33 Y = HEIGHT OF WATER AT CURB FACE (0.4' MAXIMUM) REFER TO CHART 1-104.12 L = LENGTH OF CLEAR OPENING OF INLET *Use A=O when the in1et is adjacent to traffic; i.e •• for a Type "J" median inlet or where the parking lane is removed. CITY Or SAN DIEGO -OESIGN GUIDE CAPACITY OF CURB OPENlNG INLETS ' ........ ,,·· .. ~A -'1.1.. SHT. NO. ~ -------- - - - - - - - - --.. ----..... -- > I ~ t-W UJ U. ?; W U ~ t-en 5 w en 0: :) 0 U 0: I1J I-~ 1001 1,5 I #/// ~ t~ ~;/*:/F:7t' 130 0 ~I 10 EXAMPLE: Given: Watercourse Distance (D) = 70 Feel Slope (s}=1.3'Yc Runoff Coefficient (C) = 0.4 t Overtand FJowTime (T) = 9.S Minutes T = 1.8 (1.1-C) Vff sVs SOURCE: Ai"port Drainage, Federal Aviation Administration, 1965 FIGURE. Rational Formula -OYefland nme of Flow No"mograph 3·3 ------. ~ • , '" . ~ . 7-42 JlANDnooJC OJ.' Hl."UUA ULICS D • -1.'1 1.82 1.13 I.M l.8~ "'4 1.87 1.18 1.89 1.00 •. '1 l.CI2 1.93 1.04 I.D~ ••• 0 U1 1.118 I.e~ 2.00 2.01 2.02 Table 7-10. Values of K in Formula Q -! D'i"H for n Trapezoidal Chanhcl~ (Concluded) D -d."lb of ... ,... • -boUom "idlh 0' ebaanlll Sid •• Iope. 01 channel, ratio or bOriaontal to vertIcal V ... Yt-I H-l ~-l 1-1 lH-l %-1 2)H 3-1 4-1 lical -----------.2.0 .6U .In 1.10 1.37 ).00 241 2.1H a.iO Uo .203 .640 .'13 1.09 1.37 UO ~.U 2.Ot 3.39 4030 •• il .~l7 .110 1.00 1.37 1.90 2.41 2.90 3.39 f,35 .2~O .63.' .B07 1.()9 1.38 I.8g 2.40 2.90 3.39 4.35 .2811 .All .'Of 1.01 1.30 1.80 2.40 UO 3.38 t.3t .284 .621 .101 1.08 1.30 1.19 2.40 2.110 3.38 f.3' .282 .62S .797 1.08 1.36 1.88 2.30 2.8~ 3.38 '.3. .210 .422 .711f 1.07 1.3$ 1.88 2.3D Us 3.37 4.33 .277 .420 .701 1.07 l.n 1.118 2.3i U8 3.37 U3 .:m .'17 .788 1.07 1.3' 1.87 2.31 2.111 3.37 4.33 .273 .• u .185 1.00 l.U 1.&1 2.38 2.87 3.311 4.32 .270 .613 .112 1.00 1.34 1.117 2.31 2.87 3.30 4.32 .201 .~Oll .7711 1.00 U3 1.80 2.:17 2.87 3.38 4.32 .284 .60a .11' ).O~ 1.33 1.80 2.37 2.85 3.34 4.31 .26' .60' .7,. 1.01 1.33 1.86 2.31 lI.U 3.36 4.31 .,,, .aOI .771 1.05 'J.n U.s 2.3/1 2.84 3.35 UI .200 •• :l1l .7e. 1.04 1.32 I.U 2.30 2.115 3.34 '.30 .2Sa .490 .76S 1.0. 1.32 1.85 2.35 2.6$ 3.34 •• 30 .2~5 •• 84 .7112 1.0' 1.31 1.84 2.35 2.85 3.34 4030 .2~' .4111 .700 1.0t 1.31 1.8{ 2.U a.8' 3.33 ".21l .262 .UIl .767 1.03 1.31 1.84 2.35 2.M 3.33 U~ .2$0 .487 .1$, 1.03 1.30 I.U 2.Jt 2.U ,3.33 4,29 2.03 ' .2.8 .484 .7~2 '1.03 1.30 1.8:J 2.34 2." 3.32 2.04 4.21 .2C7 .412 .HIl 1.02 1.30 1.83 2.31 2.83 3.32 '.25 2.O.s .246 ,'.0 .h' 1.02 1.30 1.'2 2.33 2.'3 3.32 , '.2, 2,00 .2C3 .411 .Ut 1.03 1.2. 1.82 '.33 Z.83 ' 3.31 U8 2.07 .2U .474 .1H 1.02 •• 211 1.112 2.33 2.82 3.3. '.27 2.01 .:13' .473 .731l 1.01 Ull U2 2.33 2.Sa 3.31 U7 2.1Xl .2)1 .471 .730 1.01 1.21 1.11 '.32 2.11a 3.31 Ul, 2.10 .234 .400 .13t 1.01 U. ' 1.11 2.32 '-'I a.30 uo 2.11 .234 .toO .732 1.00G US UI '.32 2.81 3.30 4.2& 2.12 .232 .4a4 .720 1.004 •• 21 1.11 2.31 2.81 3.30 •• 20 2.13 .231 .le2 .727 1.001 l.n 1.110 UI 2.81 3~20 '.25 2.14 .22t •• 00 .724 .1I111l 1.21 1.110 2.31 2.110 3.2i •• 24 ' 2.16 .221 .461 .722 .ue _1.27 •• 10 2.31 :1.110 3.20 '.26 1.lt .22' .u. .720 ••• t l.n 1.7,' 3.30 1.110 3.2' '.2&, 2.17 .22( .. " .111 .11111 1.2& MD 2.30 '.80 3.:<1 •. 2' 2.1 a .223 ,.U2 .71$ • 1l8' 1.20 1.7" 2.30 2.711 2.21 402& 2.1 e .2'21 . .ao .713 .1lS1 1,28 , 1.71l 2.211 2.711 3.28 U( 2;2 o .210 ~ ... .711 .014 !-lI' l.~. ' 2.20 2.78 3.20 4.24 2.:l I .'11 .... .1W .'82 J.25 1.78 2.211 2.78 3.:7 U3 2,2 2 .21e •• tt .705 .,eo l.25 1.71 !U1O " 2.7S 3.~7 4.23 2.23 .2U • 442 .10 • .'71 1.24 1.11 '.25 :.78 3.~7 '.23 2." .213 .410 .102 ;116 1.25 1.77 2.24 %.711 3.20 4.:13 2.2~ .212 .43j1 .700 .1173 1.2. 1.77 2.28 2.77 3.20 U2 . .000 .001 .,274 .500 .743 '.2. i.74 U3, ' 2.71 3.47 , " I ,. '. ., , .. '. '. I .I.. ' . .. ,. :i'fEAln-UNU'O\Ul "-LOW IN OPEN CHANNELS 1-4:J . K' Table 7-11. Vnllles of K' in Formula Q - -b'S.di ror n Trnpczuidal Channels D -deptb or water , -LoHom "'idlh 01 ell.nnel D Sid •• IOPei or channel. r.'io or horilonlal 10 Ylrtloal r Ver-tie.1 ){-l H-l JH 1-1 l)f-l 2-1 2H-I 3-1 f-I ------------.01 .00068 .00008 .00060 .00009 .00009 .00069 .00009 .00000 .00070 .ood!( .02 .00213 .OO2U .00210 .00217 .00218 .00l20 .00221 .00222 .00223 .0022! .03 .00414 .OOug .oom .oom .oom .oom .00436 .COUII .00H3 .OOti~ .Of .00660 .00610 .00(;10 .00(l8~ .00UDl .00100 .00103 .007Ui .oon:} .0073 .O~ .OO!Hu .OODIH .000?8 .OOOU .01002 .010111 .0103:1 .010n .01000 .0IOIiU .06 .0127 •• .0130 .0132 .013i .0130 .0138 .OUI .0143 .Olta .0150 .07 .OIO~ .0180 .0110 .0173 .017~ .0180 • . 0183 .0117 .oleo .Ole7 .08 .020Q .020(1 .0211 .n21S .0210 .0225 .023~ .0234 .02(0 .02S0 .00 .0241 . • 02411 .02515 .0202 .0207 .0275 .0:182 .0280 .02110 .0l10 .10 .028'-.0204 .030' .0311 .031& .03211 .0330 .03'~ .036& .0370 .n .O321l .03il .0311' .030« .0373 .03117 .0400 .0.13 .0«2t .0441 .12 .0376 .0303 .DtOI .Qno .0431 .0460 .0.011 .0482 .0.01 .O~27 .13 .0425 . . 044' .0.04 .OUO .0403 .0510 .05!!7 .05511 .0515 .OUI3 .It .omt .0302 .052( ;05(2 .0549 .O~87 .01112 .OU3? .OG3IJ .0700 .IS .0~2a .O~~O .0535 .00015 .0U27 .01162 .0092 .072 .0140 .01104 .n .0'82 .06lt .O6~O .0070 .0700 .0740 .0777 .olln .0&40 .0917 .17 .0(\38 .01al0 .0710 .OHIS .0775 .0523 .08UO .0007 .0047 .1024 .18 .0605 .0741 .078(1 .0822 .0854 .01110 .091;3 .tOOIl .10611 .1141 .to .07~3 .08011 .011.57 .0899 .0030 .1001 .105 .1115 .1\1i\l .12i7 .20 .0812 .0870 .0931 .00711 .1021 .101l1l .l1U3 .1227 .1290 .H" .21 .0873 .0945 .101 .100 .111 .1%0 .127, .135 .142 .llId .22 .ODJ4 .101' .100 .11& .120 .130 .13!J .lt7 .16~ .171 .113 .011117 .1087 .117 .12& .130 .141 .150' .100 .1\iU .1117 .24 .IOGI .Jl6I .125 .133 .140 .1&2 .103 .173 .IM .204 .24 .112$ .a230 .133 .ua .160 .. 1113 .170-.111 .101l .232 .211 .119 :13i .142 .152 .100 .17S .180 .202 .2 IS .241 .27 .l20 .139, .151 .11l2 .l11 .1811 .203. .211 .233 .2(1(.1 .21 .132 .147 .1110 .17,2 .182 .201 .217 .234 . .2411 ;281 .29 .130 .100 .170 .i!2 .194 .~U .232 .230 .211S .:102 .30 .HO .1113 .170 .a03 .205 .22' .248 .207 .2117 .32t ,31 .IS3 .172 .lIIO .204 .21S .2«2 .2A4. .255 .300 .3f? .32 .1110 .180 .190 .216 .230 .266 .281 .304 .321 .371 .33 .107' .180 .200 .227 .2d .271 .20a .323 .:ltS .300 • 3t .17t .198 .2111 .2a8 .2M .2117 .3(1). • .3U .310 .423 .36 .181 .207 .230 .261 .2BO .30a .33« .• 3U3 .382 •• 60 .30 .180 .210 .241 .20:1 .28:1 .310 .303· .385 .410 .471 .37 .100 .22~ .252 .276 .207 .330 .372 .COIi .HO .~07 .311 .203 .234 .2113 .288 .312 .353 .302 .420 .4US .ld? .3D .211 .2tt .274 .301 :g~f ' .311 .413 .462 .4111 .6118 .40 .lUII .253 -.210 .315 .389 .t3' . .no .~I' ;000 .' , .033 .ff ' .no .203 .297 .328 .357 •• 08 .460 .GOI .0tO .42 .233 .273 .3011 .3U .373 .427 .474· .6~(J' .614 .11118 .43 .241 .283 .32( .367 .380 ·.447 .601, .6&3 .003 .10.1 .tt .248 .203 .33' .371 .406 .401 -.624 .680 .033 .7'0 .U .2~0 .303 .340 .386 ;U2 .Ut .6111 .007 .00' .717 .. i.; .; .... '. : .. .. . ' .. I I I I I I I I I I I I I I I I I I I ATTACHMENT D APPENDIX ------------------- MONITORING RECORD RECOMMENDA nONS INSPECTION DATE OF OBSERV A nONS/ FOR REPAIR! DATE OF DATE STORM INSPECTOR COMMENTS MAINTENANCE MAINTENANCE .. Signed By: _____ ~ ________ _'__ _____ _ Date.:, __________ _ I I I I I I I I .1 I I I' I I I I. I I I All amendments made to this SWMP shall be documented in thistable. DATE: Prepared By Partners Planning and Engineering BY: DESCRIPTION \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 I I I I I I I I I I I I I I I I I I I CONTACT PHONE PERSON NUMBER Prepared By Partners Planning and Engineering ALTERNATE PHONE NUMBER ALTERNATE CONTACT PERSON - \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 PHONE NUMBER I I I I I I I I I I I I I I I I I I· I ATTACHMENT E OPERATION AND MAINTENANCE PLAN Prepared By Partners Planning and Engineering \\Server\c-drive\dwg\577\577 -swmp.doc 1/16/2006 ·---~--.-.-.-•. -'-.-.--- Estimated 0 & M Costs for BMP Estimated values derived from Caltrans Pilot BMP Study. This spreadsheet will change as addllional data becomes available. 810FIL TER -STRIPS and SWALES 1 Preventive Maintenance and Routine Inspections ROutTNl:AC1TONS-IMAINTENANCE INDICATOR Height of vegetation Assess adequate vegetative cover Average vegetation height exceeds 12 Inches emergence of trees, or woody vegetaton. Less than 90 percent coverage In stnp Invert/swale or less than 70 percent on swale side slope FIELD rEASUREMENT MEASUREMENT FREQUENCY '\~'J:I,"(~; .. :~~~a/ :~:;,r~~'> Once during wet Visual inspection of reason, once during vegetation throU9ho~t dry season, (depending slrip/swale _ on growth) _ Visual Inspecllon of stnp/swale. Prepare a site SchematiC to record tocatlon and dlstnbutlon of baren or browning spots to be restored. File the schematic for assessment of persistent problems. ASsess quantity needed in May each year late wet season and late dry season . :._~ __ !.t. .A·: '...]'--.;: ... ' "\ .. .:~ MAINTENANCE IT -SPECIFIC ACTIVITY FREQUIREMENTS "'<;')~:~~u;, ~i.;~f:f~~~::'-: ·:tjfiY;:';~k~;f<,~:~'.s, ,': Cut vegetation to an Remove any trees, average height of 6 or woody Inches Reseed/revegetate barren spots by Nov, Scarify ~~e~:t~ ~e restorEid, to a depth of 2- inches. Restore side slope coverage with hydroseed mixture. If after 2 applications (2 seasons) of reseedingfrevegetating and growth is unsuccessful both times, an erosion blanket or I equivalent protection will be installed OVElr eroding areas .• vegetation , .. ~~! .t"-!, • .: ',:' ... Inspect for debris accumulation '. ,~, '" ' .. '.' 'ID~~~iril;'~~shi~' I \::(t~:-:>,':;;~5~~":;:~:':J '~~.,:~~~'f.;;~~::; Debris or litter present Ivisual ~ation .' :', pe~ Distriqs ~~ule :.:' ReiiM?~~ 'Iitter' ~ ~ixi N~:;~~0;\t«~i "Sediment at or near vegetation height, channeling of flow, Remove sediment. If flow is channeled, determine cause and t~ke corrective action. If sediment becomes deep enough to change the , flow, gradient, remove sediment during dry season, characterize and properly dispose of I labor Per Hrs Rate 10 43.63 8 43.63 . " ~,-:-... ,":,'-', 01 43.631 o 43.63 ~t:iJt~i7,,~~:~~ Cost Type _ ...... l<,~"y~ 7:;~",:: "'~:~:"!"- truck & ~~ 1 436.3 hydroseede one-ton truck & 349,04 hydroseeder! : " one-ton truck & Olhydroseederl one-ton truck & Olhydroseede r;/i~:,; ,=': ... : ~X;·~-=. 0 hydroseede , , -~~, . one-ton -.---- Equipment' Materials I Total Comments DaysiRate ICost Item I Costl Cost 2 26.64 11 48151 01 26 841 01 26.84 •. .. .: -:. string trimmer. rake, fork. bags. safety 53.68 equipment I 48.151seed 0 Olblanket seed. testing and 501 539,98 150 547.19 o o 000 - - - --- Inspect for accumulated linhibited flow due to sediment change in slope. Visual observation Inspect for burrows Burrows, holes, mound, Visuat observation General Maintenance Inspection TOTAL BID FILTER AND SWALES Inlet structures. outlet structures. side slopes or other features damaged, significant erosion. emergence of trees. woody vegetation fence damage, etc. IVisual observation -------- Annually sediment, and revegetate. Notify engineer to determine if regrading isl necessary. If neCessary, regrade to design I specification and revegetate swale/strip. If regrading is necessary, the process should start In May. Revegetate stnp/swale in Nov. Target completion prior to wet season. None Where burrows cause Annually and after .:;::: Iseepage, erosion and vegetation trimming '::. leakage, backfill firmly. Corrective action prior to ':~~~;;i!t~:;':L :;. Semi-Annually, late Iwet season. Consult wet season. And late dry engineer if an immediat1Remove any trees, or season. solution is not evident. woody vegetation. 16 2 truck & 43.631 698 08lhydroseede 43.63 57.26 ..' ~;. (. '01 ~'.~;~~;:~ 0 one-ton truck & .,Olhydroseede 16 52 one-lon truck & 43.631 698.08lhydroseede; 2268.76 ----- disposal 11 48.151 48.1510fsediment once every 3001 1046 23lthree years o 8726 o 26.84 o o 21 26.841 53.68 751.76 203.66 5001 2.972.42 ------.--' --, -~ -' -' -' . -. -' -. -. -. Estimated 0 & M Costs for BMP DESIGN""CRITERTA iMAIf'f1 .. rU::lU II MAIN I ,~I 11::-~"'t:\..It-I\" I LaDor t:qUlpment IMatenals lotal I(;omments ROUTINE ACTION INDICATOR MEASUREMEN FREQUENCY ACTIVITY REQUIREMEN Per Hrs Rate DRAIN INLET INSERTS - Cost Type Days Rate Cost Item Cost Cost FOSSIL FILTER Estimated values derived from Callrans Pilot BMP Study. This spreadsheet will change as additional dala becomes available. Prevenlive Maintenance and Routine Inspections DESIGN CRITERIA ROUTINE ACTIONS Sufficient debrisl trash that could Interfere with proper Inspect for DebrisfTrash functioning of inset Visual observation During the wet season 43.83 0 0 0 Remove and properly dispose of debrisJ Irash. Target :J Before and once during complelion period each target2 storm while onsite (0.25in) event conducting inspection 18 43.63 785.34 0 785.34 Replace Fossil Filterl • TM absorbent wilhin 10 working days. Absorbent granules Characterize and dark gray. or darker, JAllhe end of each properly dispose or until Clogged Wltn target;! storm (0.2::>ln) spent media pnor to 011 and grease removal sediment Visual observation event. wei season. 2 43.63 87.26 0 87.26 Replace insert or Immediately consull veneor to aevelop COUrse of action, Inspection for structural Broken or otherwise Twice per year in <9ffect repairs wilhin 10 integrity damaged insert Visual observation October and May working days None 2 43.63 87.26 0 8726 new adsorb- Remove, characterize, entlest- and properly dispose ing& End of wet season, of. media & Reptace disposal Annual renewal of medium 30-Apr None Annul'lIy, in May .' media before Oct. 1 None 2 43.63 87.29 sedan 1 21.28 21.28 costs 115 223.~ TOTAL DRAIN INLET INSERTS-FOSSIL FILTERS 24 1047.12 21.28 115 1.183.4 .~-- ._-------------------------------------------------------------------------------------------------- I ( \ ~--- -------------.-\ BUILDING 1 fFJ((})§ Tr ~(C ([JJ JF!/ § Tr lR1 [JJJ (C Tr /l (()) JF!/ lE3Ji';f]fFJ ~ lE3lRl IE §§ /l lRlAJJF!/ (C[!={f ([JJ lL (()) Tr . t{) @ --------- --------I I 2:1 -- ~----------~~~----J -----,--j------ ----------- MANHOLE FLO-GARD'" INSERT CATCH BASIN - CATCH BASIN GUTTER [FLOWLINE HANDLES GASKET" CURB OPENING REMOVABLE FILTER BASKET (SEE NOTE 6) ~....--'I-+ GUTTER FLOWLINE FLO-GARD FILTER BODY FOSSIL FILTER FLO-GARD SUPPLEMENTAL INSERT FOR ON-SITE PRIVATE CURB OPENING INLET BUILDING 3 BUILDING 2 BUILDING 13 --=-~,.r--:: ---~.----~;,:;;:;;;~ BUILDING 14 • BUILDING 4 • BUILDING 7 • BUILDING 8 """ "" I BUILDING 9 • BUILDING 10 SCALE: r = 50' INLET GRATING DRAINAGE INLET-----' I I - I !sf ! I , FINISHED FLOO? DEEPENED FOO'TlNG:,',S*I FOSSIL FILTER DETAIL NOT TO SCALE I' i ") I r I I I FILTER BODY ____ , FILTER BASKET FOSSIL ROCK '" FILTER ~ MEDIUM POUCH '>i FILTER BODY , . 3/8" X 3" ANCHOR BOLT (3 PER SECTION) NOTES: 1. FLO-GARD'" fiLTER BODY SHALL BE MANUFACTURED FROM PE7ROLEUM RESISTANT fiBERGLASS !tHICH MEETS OR EXCEEDS PS 15-69. 2. ALL METAL COMPONENTS SHALL BE STAINLESS STill (T'rPE 304). J. REMOVABLE fiLTER BASKET SHALL BE CONS7RUCTED FROM DURABLE POLYPROPYlENE WOVEN MONOFILAMENT GEOTEXTILE. 4. FLO-GARD'" fiLTER BOOY SHAll BE SECURED TO CATCH BASIN WALL II1TH EXPANSION ANCHOR BOLTS AND WASHER (SEE DETAIL). , i I SIDE VIEW ANCHOR DETAIL 5. FLO-GARlJ" INSERTS ARE AVAILABLE IN 24" OR 30" LENGTH SECTIONS AND MA Y BE INSTALLED IN VARIOUS COMBINA TlONS (END TO END) TO fIT MOST CA TCH BASIS II1DTHS. 6. flL TER BASKET MA Y BE REMOVED THROLfGH CURB OPENING FOR EASE OF MAINTENANCE. , SCALE: NONE ! , , ,I , , , , : I ! I ! , I ! , , i ,. , , i , !t , I \ VARIES f:I--BUILDING SKIN 5.0' SWALE CROSS SECTION FOSSIL FlL TER NOT TO SCALE INSTALLA TlON NOTE: 1. REMOVE INLET GRA TlNG AND MEASURE INSIDE DIMENSION OF INLET. 2. CUT FOSSIL FIL TER CORNER SECTIONS TO APPROPRIA TE LENGTHS. 3. CONNECT CORNER SECTIONS TOGETHER AND SET FOSSIL FlL TER INTO INLET (RESTING ON BEARING SURFACE.) 4. CUT THE FlL TER CAR7RIDGE TO FIT FOSSIL FlL TER. 5. PLACE END CAP ON ONE END OF FILTER CAR7RIDGE AND FILL UNIT FROM OPEN END l't1T11 ABSORBENT. 6. PLACE OTIIER END CAP ON FlL TER CAR7RIDGE AND PLACE FILLED UNIT INTO THE INSTALLED FOSSIL FILTER. INSTALLA TlON IS COMPLETE. 7. flL TER MEOIUM SHALL BE FOSSIL ROCK"', IN DISPOSABLE POLfCHE5, INSTALLED AND MAINTAINED IN ACCORDANCE II1TH MANUFACTURER RECOMMENDATIONS. 8. PROPERTY OIfNER SHALL MAINTAIN FILTER IN ACCORDANCE II1TH MANUFACTURER RECOMMENDA TlONS. THERE ARE SEVERAL FACTORS TO BE CONSIDERED !tHEN SELECTING COANDA DOWNSPOUT FILTER. COANDA DOIfNPOUT FILTERS ARE AVAILABLE IN SEVERAL STANDARD SIZES AND CAN BE CUSTOM ORDERED. VARIABLES INCLUDE ANGLE OF THE SCREEN, II1RE SPACING, DOIfNSPOLfT CONFIGURA TlON (SOLfARE OR RECTANGULAR)' METHOD OF DEBRIS CAPTURE, INTERIOR OR EXTERIOR MOUNT, AND FLOW CAPACITY REQUIREMENTS. OPTIONS INCLUDE THE ADDITION OF A HYDROCARBON flL TRA TlON. DOIfNSPOUT SIZE (inches) 4 TOP I1EW , . ',';' . , .. ," . , FLOW CAPACITY MODEL NUMBER (gpm) (In lerior /Exterior) 175 OFS-4-1 OR E . , DETAIL RIGHT. • THE EDGE OF THE SCREEN CREA TES A SHEARING EFFECT AS WA TER FLOWS ACROSS THE SURF A CE, OIl£!? TlNG WA TER THROLfGH THE SCREEN !tHILE DEBRIS SLIDES OFF TIlE FACE OF THE SCREEN. WATERFLOW DIRECT/ON PRIOR TO FLOfllNG THROUGH THROUGH SCREEN(T'rP ). AS SHOIfN ON THE LEFT, WATER PASSES UNIMPEDED THROUGH THE SCREEN !tHILE DEBRIS IS COLLECTED OUTSIDE THE DOIfNSPOLfT. DEBRIS MA Y BE COLLECTED IN A CONTAINER OR BASKET MOUNTED TO THE SCREEN, OR SlMPL Y COLLECTED FOR MANUAL REMOVAL AT A LATER TIME. THE DOIfNSPOUT MA Y BE MOLfNTED INSIDE THE BUILDING AS SHOWN, OR IF PREFERRED, AGAINST THE OUTSIDE WALL. DETAIL: COANDA DOWNSPOUT FlL TER (PVT) PARTNERS Planning and Engineering NOT TO SCALE NOTE: ONLY BUILDINGS 6-11 TO BE FllTED WITH COANDA DOWNSPOUT FILTERS. 15938 Bernardo Center Drive San Diego, CA. 92127 Ph. (858) 376-3444 Fax: (858)376-3555 E a. "' "' n '" "' o I '" ~ 40 -______ c~'--'--~ ___ _ , , '" .: ~'.:':t -;~:~':::/:-, _:",1' ;~::.~ ~ '.~:~' .~~ :. ,/;': ',,:; ..... , ,; : : " ' ,.('. " :, , ' ' .. RR®RGSElB"I:1YDROlLOGY<"EXPfIBIT::" " 0 <":~;'B~RES8'1 'RAN.OR: LJ3T;·;····4t)':;.' , . , >'. , " ", . ', , " ,.' " .. "t' • .. '." ,. ,,' ;" '.: " ; . ' " • < , ,'. -" .... ',-' : .,.' , ... ,~ . ~ , ,,: .. , . ':. ' .. '." , , n,', : :' :,~:SrR(iCtrJRE NO., .. ' . -'.' ;, .'. . "BA'Siilplr(l[ ~II!-~ ....... '!""'.... ......fIoio! ,,:,: iJiREc77oN, or naw , " . ", . " ," .'; :' ," .. , '. ~ ". " ,':' . ,. -:, '." . -, ' ~, ... :;.,:- . ~ ,,- . ': " .. "'., ':. ;'" .' .1, , , ,',' ": . ,', :,. ", , " , " \ GRAPH/CAL' SCALE ' ' , " '" .. ~: , " . .~ . . " SCALE: Job no, 44i'i,U .. "