[Ord. No. 1528, 9-26-2022]
The Pennsylvania Stormwater Best Management Practices Manual shall serve as a guide for the design of stormwater management practices. Additional design guidance may also be obtained from other related sources, including the 2000 Maryland Stormwater Design Manual, Volumes I and II (MDE, 2000), Design of Stormwater Filtering Systems (CWP, 1996), and the American Society of Civil Engineers Manual and Report on Engineering Practice, No. 87, Urban Runoff Quality Management (ASCE, 1998), for the design of stormwater runoff quality control features for site development. A list of references is provided with this article. The water quality volume design measures used herein are partially based on the methodology expressed in the Maryland Manual referenced above. Pursuant to the design options recommended in the above documents, the following standards shall be adhered to:
(a) Extended detention, water quality volume, infiltration and nonstructural BMP credits criteria. The following sizing criteria shall be followed at all sites required to meet the standards of this article:
(1) Extended detention.
A. Detain the one-year, twenty-four-hour design storm using the SCS Type II distribution. The design of the facility shall consider and minimize the chances of clogging and sedimentation potential.
B. Detention basins shall detain the one-year storm event and allow it to naturally infiltrate and recharge the groundwater table if possible. All subsequent orifices and control structures for the two-, ten-, twenty-five- and 100-year storm events shall be placed above the maximum water surface elevation of the one-year storm.
C. Flow from off-site areas must be considered as pass-through flow if it is conveyed through the BMP and should be modeled as predeveloped conditions for the one-year storm event only.
(2) Water quality volume.
A. Treatment of the water quality volume (WQv) of stormwater prior to its release to receiving waters or water bodies shall be provided at all developments where stormwater management is required. The WQv equals the storage volume needed to capture and treat the runoff from storms of one inch or less. Runoff from the first one inch of rainfall transports most of the total pollutant load. The WQv is based on the following equation:
WQv = [(P)(Rv)(A)]/12 (acre-feet) |
Where: |
P | = | Rainfall depth in inches (set to one inch). |
Rv | = | Volumetric runoff coefficient, 0.05 + 0.009(1), where 1 is percent impervious cover. |
A | = | Site area (acres). |
B. The formula assumes approximately 5% runoff from pervious surfaces and 90% runoff from impervious surfaces. A minimum of 0.2 inch per acre of runoff volume shall be met at sites or in drainage areas that have less than 15% impervious cover.
C. Drainage areas having no impervious cover and no proposed disturbance during development may be excluded from the WQv calculations. However, designers are encouraged to incorporate water quality treatment practices for these areas.
D. Stormwater quality treatment. The final WQv shall be treated by an acceptable stormwater management practice(s) from those described in this section or as approved by the Town.
E. For new developments and redevelopments, infiltration is considered an acceptable method of satisfying part or all of the water quality volume.
F. For new developments, the WQv requirements of this section shall be sized and designed in conjunction with the standards under §
913.16(a)(1).
G. As a basis for design, the following assumptions may be made:
1. Multiple drainage areas. When a project contains or is divided by multiple drainage areas, the WQv volume shall be addressed for each drainage area.
2. Off-site drainage areas. The WQv shall be based on the impervious cover of the proposed site. Off-site existing impervious areas may be excluded from the calculation of the water quality volume requirements.
(3) Infiltration volume. Where possible, all of the water quality volume should be treated using infiltration BMPs. The following calculation shall be used to determine the minimum recharge goal for the site:
Recharge Volume (Rev), (acre-feet) |
Fraction of WQv, depending on soil hydrologic group. Rev = (S)(Ai) |
Where: |
S | = | Soil-specific recharge factor in inches. |
Ai | = | The measured impervious cover. |
Hydrologic Soil Group | Soil-Specific Recharge Factor (S) (inch of runoff) |
|---|
A | 0.40 |
B | 0.25 |
C | 0.10 |
D | 0.05 |
A. Infiltrated volume may be subtracted from the total site WQv.
B. Infiltration should not be considered for sites or areas of sites that have activities that may allow pollution to be infiltrated. For example, the use of infiltration for the runoff of a service station's paved lot would not be appropriate, although roof water from the service station may be infiltrated.
C. Infiltration should only be used when, in the opinion of a professional engineer, it will not contribute to slope instability or cause seepage problems into basements or developed downgradient areas.
D. If more than one hydrologic soil group is present at a site, a composite recharge volume shall be computed based upon the proportion of total site area within each hydrologic soil group.
E. All infiltration facilities shall be set back at least 20 feet from all structures with subgrade elements (e.g., basements, foundation walls).
F. All infiltration facilities shall be set back at least 20 feet from all property lines and road rights-of-way.
G. A detailed, on-site infiltration test is required at the location of all infiltration BMPs.
(4) Credits for use of nonstructural BMPs. The developer may obtain credits for the use of nonstructural BMPs using the procedures outlined below. Examples of nonstructural credit calculations are provided in Appendix E.
A. Volume Reduction Method No. 1: Natural Area Conservation.
1. A water quality volume reduction can be taken when undisturbed natural areas are conserved on a site, thereby retaining their predevelopment hydrologic and water quality characteristics. Under this method, a designer would be able to subtract the conservation areas from the total site area when computing the water quality protection volume. An added benefit is that the post-development peak discharges will be smaller, and hence, water quantity control volumes will be reduced due to lower post-development curve numbers or Rational Formula "C" values.
2. Rule. Subtract conservation areas from total site area when computing water quality protection volume requirements.
3. Criteria.
(A) Conservation area cannot be disturbed during project construction and must be protected from sediment deposition. The conservation area shall be protected with a safety fence until construction has been completed. After construction, the area shall be posted with signage indicating that it is a conservation area.
(B) Shall be protected by limits of disturbance clearly shown on all construction drawings.
(C) Shall be located within an acceptable conservation easement instrument that ensures perpetual protection of the proposed area. The easement must clearly specify how the natural area vegetation shall be managed and boundaries will be marked. [Note: Managed turf (e.g., playgrounds, regularly maintained open areas) is not an acceptable form of vegetation management.]
(D) Shall have a minimum contiguous area requirement of 10,000 square feet.
(E) Rv is kept constant when calculating WQv.
(F) Must be forested or have a stable, natural ground cover.
B. Volume Reduction Method No. 2: Stream Buffers.
1. This reduction can be taken when a stream buffer effectively treats stormwater runoff. Effective treatment constitutes treating runoff through overland flow in a naturally vegetated or forested buffer. Under the proposed method, a designer would be able to subtract areas draining via overland flow to the buffer from total site area when computing water quality protection volume requirements. The design of the stream buffer treatment system must use appropriate methods for conveying flows above the annual recurrence (one-year storm) event.
2. Rule. Subtract areas draining via overland flow to the buffer from total site area when computing water quality protection volume requirements.
3. Criteria.
(A) The minimum undisturbed buffer width shall be 50 feet from top of bank.
(B) The maximum contributing length shall be 150 feet for pervious surfaces and 75 feet for impervious surfaces.
(C) The average contributing slope shall be 3% maximum unless a flow spreader is used. In no case shall the average contributing slope be greater than 10%.
(D) Runoff shall enter the buffer as overland sheet flow. A flow spreader can be installed to ensure this.
(E) Buffers shall remain as naturally vegetated or forested areas and will require only routine debris removal or erosion repairs.
(F) Rv is kept constant when calculating WQv.
(G) Not applicable if overland flow filtration/groundwater recharge reduction is already being taken.
C. Volume Reduction Method No. 3: Enhanced Swales.
1. This reduction may be taken when enhanced swales are used for water quality protection. Under the proposed method, a designer would be able to subtract the areas draining to an enhanced swale from total site area when computing water quality protection volume requirements. An enhanced swale can fully meet the water quality protection volume requirements for certain kinds of low-density residential development. (See Volume Reduction Method No. 5.) An added benefit is the post-development peak discharges will likely be lower due to a longer time of concentration for the site.
2. Rule. Subtract the areas draining to an enhanced swale from total site area when computing water quality protection volume requirements.
3. Criteria.
(A) This method is typically only applicable to moderate- or low-density residential land uses (three dwelling units per acre maximum).
(B) The maximum flow velocity for the water quality design storm shall be less than or equal to 1.0 foot per second.
(C) The minimum residence time for the water quality storm shall be five minutes.
(D) The bottom width shall be a maximum of six feet. If a larger channel is needed, use of a compound cross section is required.
(E) The side slopes shall be 3:1 (horizontal:vertical) or flatter.
(F) The channel slope shall be 3% or less.
(G) Rv is kept constant when calculating WQv.
D. Volume Reduction Method No. 4: Overland Flow Filtration/Groundwater Recharge Zones.
1. This reduction can be taken when overland flow filtration/infiltration zones are incorporated into the site design to receive runoff from rooftops or other small impervious areas (e.g., driveways, small parking lots, etc.). This can be achieved by grading the site to promote overland vegetative filtering or by providing infiltration or rain garden areas. If impervious areas are adequately disconnected, they can be deducted from total site area when computing the water quality protection volume requirements. An added benefit will be that the post-development peak discharges will likely be lower due to a longer time of concentration for the site.
2. Rule. If impervious areas are adequately disconnected, they can be deducted from total site area when computing the water quality protection volume requirements.
3. Criteria.
(A) Relatively permeable soils (Hydrologic Soil Groups A and B) should be present.
(B) Runoff shall not come from a designated hotspot.
(C) The maximum contributing impervious flow path length shall be 75 feet.
(D) Downspouts shall be at least 10 feet away from the nearest impervious surface to discourage reconnections.
(E) The disconnection shall drain continuously through a vegetated channel, swale, or filter strip to the property line or structural stormwater control.
(F) The length of the disconnection shall be equal to or greater than the contributing length.
(G) The entire vegetative disconnection shall be on a slope less than or equal to 3%.
(H) The surface impervious area tributary to any one discharge location shall not exceed 5,000 square feet.
(I) For those areas draining directly to a buffer, reduction can be obtained from either overland flow filtration or stream buffers. (See Method No. 2.)
(J) Rv is kept constant when calculating WQv.
E. Volume Reduction Method No. 5: Environmentally Sensitive Large-Lot Subdivisions.
1. This reduction can be taken when a group of environmental site design techniques are applied to low- and very-low-density residential development [e.g., one dwelling unit per two acres (du/ac) or lower]. The use of this method can eliminate the need for structural stormwater controls to treat water quality protection volume requirements. This method is targeted towards large-lot subdivisions and will likely have limited application.
2. Rule: targeted towards large-lot subdivisions (e.g., two- acre lots and greater). The requirement for structural facilities to treat the water quality protection volume may be waived.
3. Criteria.
(A) For single-lot development:
a. Total site impervious cover is less than 15%.
b. Lot size shall be at least two acres.
c. Rooftop runoff is disconnected in accordance with the criteria in Method No. 4.
d. Grass channels are used to convey runoff versus curb and gutter.
(B) For multiple lots:
a. Total impervious cover footprint shall be less than 15% of the area.
b. Lot areas should be at least two acres, unless clustering is implemented. Open space developments should have a minimum of 25% of the site protected as natural conservation areas and shall be at least a half-acre average individual lot size.
c. Grass channels should be used to convey runoff versus curb and gutter (see Method No. 3).
d. Overland flow filtration/infiltration zones should be established (see Method No. 4).
(b) Stormwater infiltration practices.
(1) In selecting the appropriate infiltration BMPs, the applicant shall consider the following:
A. Permeability and infiltration rate of the site soils.
B. Slope and depth to bedrock.
C. Seasonal high water table.
D. Proximity to building foundations and wellheads.
F. Land availability and topography.
H. Effects on nearby properties and structures.
(2) Loading ratios.
A. The loading ratio of impervious surface to infiltration bed bottom size must be considered in all designs. The loading ratio describes the ratio of impervious drainage area to infiltration area, or the ratio of total drainage area to infiltration area. The following loading ratios may not be exceeded:
1. Maximum impervious loading ratio of 5:1 relating impervious surface draining to a particular infiltration area.
2. Maximum total loading ratio of 8:1 relating total drainage area to infiltration area.
3. Maximum impervious loading ratio of 3:1 relating impervious drainage area to infiltration area for Karst topography.
B. If a BMP is proposed to exceed any of these values, a detailed geotechnical analysis prepared by a licensed geotechnical engineer will be required to determine the overall effects to downstream properties should the load ratios be exceeded. Items such as groundwater mounding and the potential for subsurface flooding of downstream structures should be clearly addressed. The Town Engineer will review this analysis and render an opinion on the viability of the property design.
(3) A detailed soils evaluation of the project site shall be performed to determine the suitability of infiltration BMPs. The evaluation shall be performed by a qualified professional and, at a minimum, address soil permeability, depth to bedrock and slope stability. The general process for designing the infiltration BMP shall be:
A. Analyze hydrologic soil groups as well as natural and man-made features within the watershed to determine general areas of suitability for infiltration BMPs.
B. Provide field testing data to determine appropriate percolation rate and/or hydraulic connectivity.
C. Design infiltration BMPs for required stormwater volume based on field-determined capacity at the level of the proposed infiltration surface.
(4) Soil characteristics are subject to the specific considerations below:
A. Infiltration BMPs are particularly appropriate in Hydrologic Soil Groups A and B, as described in the Natural Resources Conservation Manual TR-55.
B. Low-erodibility factors ("K" factors) are preferred for the construction of basins.
C. There must be a minimum of 24 inches between the bottom of any facility (i.e., basin bottom for noninfiltration facilitates or infiltration media bottom for facilities) and the seasonal high water table and/or bedrock (limiting zones) for facilitates located outside floodplains. There must be a minimum of 48 inches between the bottom of any facility (i.e., basin bottom for noninfiltration facilitates or infiltration media bottom for facilities) and the seasonal high water table and/or bedrock (limiting zones) for facilitates located within floodplains.
D. There must be an infiltration and/or percolation rate sufficient to accept the additional stormwater load and to drain completely as determined by field tests.
E. The infiltration system shall have positive overflow controls to prevent storage within one foot of the finished surface or grade.
F. Infiltration rates shall not be used for computing the storage volume of the infiltration system.
G. Surface inflows shall be designed to prevent direct discharge of sediment into the infiltration system.
(5) The recharge volume provided at the site shall be directed to the most permeable hydrologic soil group available, except where other considerations apply, such as in limestone geology.
(6) Any infiltration BMP shall be capable of completely infiltrating the impounded water within 48 hours. The forty-eight-hour period is to be measured from the end of the twenty-four-hour design storm.
(7) The Town may require additional analyses for stormwater management facilities proposed for susceptible areas such as:
B. Storage areas for salt, chloride, other materials for winter deicing.
C. Unstable and steep slopes.
(8) During the period of land disturbance, runoff shall be controlled prior to entering any proposed infiltration area. Areas proposed for infiltration BMPs shall be protected from sedimentation and compaction during the construction phase so as to maintain their maximum infiltration capacity.
(9) Infiltration BMPs shall not be constructed nor receive runoff until the entire contributory drainage area to the infiltration BMP has received final stabilization.
(10) Infiltration facilities shall be selected based on suitability of soils and site conditions. Acceptable infiltration includes but is not limited to: filter strips or stormwater filtering systems (for example, bioretention facilities, sand filters), open vegetated channels (that is, dry swales and wet swales), infiltration trenches, dry wells, infiltration basins, porous paving systems, retention basins, wet extended detention ponds, riparian corridor management, riparian forested buffers, rooftop runoff management systems, and sand filters (closed or open).
(11) Where sediment transport in the stormwater runoff is anticipated to reach the infiltration system, appropriate permanent measures to prevent or collect sediment shall be installed prior to discharge to the infiltration system.
(12) Large infiltration facilities, such as retention basins or detention ponds, shall be set back at least 20 feet from all habitable structures with subgrade elements (e.g., basements, foundation walls). Small infiltration facilities, such as rain gardens or vegetated swales, may be set back 10 feet from habitable structures with subgrade elements.
(13) All infiltration facilities that serve more than one lot and are considered a common facility shall have a private drainage easement. The easement shall provide to the Town the right of access.
(14) If detailed infiltration study is required, the following guidelines shall be followed:
A. Soil evaluations shall be performed to determine the feasibility and extent to which infiltration systems can be used. The evaluation shall be performed by a qualified, licensed geologist, geotechnical/civil engineer, or soil scientist and, at a minimum, address soil types, soil permeability, depth to bedrock, limitations of soils, presence/absence of carbonate geology, susceptibility to subsidence and/or sinkhole formation, and subgrade stability. The testing and evaluation should be completed at the preliminary design stage.
B. Infiltration requirements shall be based on the portions of the site that are permeable prior to disturbance and the degree to which development will reduce the permeability of the site. Permeability of the site shall be determined based on the detailed evaluations described herein. Use of stormwater management facilities to retain stormwater for infiltration should be applied to all areas where the soils evaluation indicates favorable conditions. Areas generally not favorable for infiltration shall still be provided with an appropriate water quality practice.
C. Soil infiltration tests shall be performed to an equivalent depth or elevation of the bottom of the proposed infiltration areas. These tests shall follow the procedures of percolation test holes as established by the Allegheny County Health Department (ACHD) for on-lot septic systems or Appendix C, Site Evaluation and Soil Testing, in the PA Stormwater BMP Manual.
D. The testing shall include a test pit and percolation test holes. The test hole shall be excavated to a depth so that the presence or absence of bedrock and/or seasonal high water table can be determined. A soil log describing the soils present in each test pit shall be performed. All test holes used for evaluating the percolation rate shall be presoaked in accordance with the procedures established by the ACHD. The location and number of test pits and percolation holes shall be determined based on the type(s) of stormwater management facilities being designed. Acceptability of infiltration rates shall be based on sound engineering judgment and recommended design considerations described in the design manuals listed in the references or other source material acceptable to the Engineer.
(15) The following design and construction standards shall be followed when planning and constructing infiltration BMPs:
A. The lowest elevation of the infiltration area, when located outside a floodplain, shall be at least two feet above the seasonal high water table and bedrock. The lowest elevation of the infiltration area, when located within a floodplain, shall be at least four feet above the seasonal high water table and bedrock.
B. Where roof drains are designed to discharge to infiltration facilities, they shall have appropriate measures to prevent clogging by unwanted debris (for example, silt, leaves and vegetation). Such measures shall include, but are not limited to, leaf traps, gutter guards and cleanouts.
C. All infiltration facilities shall have appropriate positive overflow controls to prevent storage within one foot of the finished surface or grade unless a specific amount of surface storage away from pedestrian and vehicular traffic is provided and such areas infiltrate the stored volume within 48 hours after the end of the twenty-four-hour design storm.
D. All infiltration facilities shall be designed to infiltrate the stored volume within 48 hours after the end of the twenty-four-hour design storm.
E. All surface inflows shall be treated to prevent the direct discharge of sediment into the infiltration facility. Accumulated sediment reduces stormwater storage capacity and ultimately clogs the infiltration mechanism. No sand, salt or other particulate matter may be applied to a porous (pervious) surface for winter ice conditions.
F. During site construction, all infiltration practice components shall be protected from compaction due to heavy equipment operation or storage of fill or construction material. Infiltration areas shall also be protected from sedimentation. Areas that are accidentally compacted or graded shall be remediated to restore soil composition and porosity. Adequate documentation to this effect shall be submitted for review by the Engineer. All areas designated for infiltration shall not receive runoff until the contributory drainage area has achieved final stabilization.
G. The following procedures and materials shall be required during the construction of all subsurface facilities:
1. Excavation for the infiltration facility shall be performed with equipment that will not compact the bottom of the seepage bed/trench or like facility.
2. The bottom of the bed and/or trench shall be scarified prior to the placement of aggregate.
3. Only clean aggregate with documented porosity, free of fines, shall be allowed.
4. The tops and sides of all seepage beds, trenches, or like facilities shall be covered with drainage fabric. Fabric shall meet the specifications of PennDOT Publication 408, Section 735, Construction Class 1.
5. Perforated distribution pipes connected to centralized catch basins and/or manholes with the provision for the collection of debris shall be provided in all facilities. Where perforated pipes are used to distribute stormwater to the infiltration practice, stormwater shall be distributed uniformly throughout the entire seepage bed/trench or like facility.
(c) Open vegetated channels.
(1) Open vegetated channels are conveyance systems that are engineered to also perform as water quality and infiltration facilities. Such systems can be used for the conveyance, retention, infiltration, and filtration of stormwater runoff.
(2) Open vegetated channels primarily serve a water quality function (WQv); they also have the potential to augment infiltration. Examples of such systems include, but are not limited to: dry swales, wet swales, grass channels, and biofilters. Open vegetated channels are primarily applicable for land uses such as roads, highways, residential developments (dry swales only) and pervious areas.
(3) Open vegetated channels shall be designed to meet the following minimum standards:
A. The channel shall be designed to safely convey the ten-year frequency storm event with a freeboard of at least 12 inches. "Freeboard" is the difference between the elevation of the design flow in the channel and the top elevation of the channel.
B. The peak velocity of the runoff from the ten-year storm shall be nonerosive for the soil and ground cover provided in the channel.
C. The longitudinal slope shall be no greater than 6%. Check dams or turf reinforcement matting is recommended for slopes between 3% and 6%.
D. Channels shall be trapezoidal in cross section.
E. Channels shall be designed with moderate side slopes of two horizontal to one vertical. Flatter side slopes may be necessary under certain circumstances.
F. The maximum allowable ponding time in the channel shall be less than 48 hours.
G. Channels (for example, dry swales) may require an underdrain in order to function and dewater.
H. Channels shall be designed to temporarily store the WQv within the system for a maximum period of 48 hours and a minimum period of one hour.
I. Landscape specifications shall address the grass species, wetland plantings (if applicable), soil amendment and hydric conditions present along the channel.
J. Accumulated sediment within the channel bottom shall be removed when 25% of the original WQv volume has been exceeded. The channel shall be provided with a permanent concrete cleanout marker that indicates the 25% loss level.
K. Check dams along the channel length may be warranted.
L. The bottom of dry swales shall be situated at least two feet above the seasonal high water table.
(4) Additional design information for open vegetated channels is available in Design of Roadside Channels with Flexible Linings, HEC 15, FHWA, September 2005.
(d) Retention basins.
(1) Retention basins shall be designed to create a healthy ecological community with sufficient circulation of water to prevent the growth of unwanted vegetation and mosquitoes or other vectors. If circulation cannot be provided via natural means, then artificial aeration and circulation shall be provided. Care shall be taken to landscape retention basins in accordance with §
913.17.
(2) The retention basin shall be of sufficient size to allow the appropriate aquatic community needed to maintain healthy pond ecology and avoid mosquitoes capable of carrying West Nile virus and other diseases. The Allegheny County Health Department, the Pennsylvania Fish and Boat Commission, the Natural Resources Conservation Service, the Pennsylvania Extension Service, or other qualified professional consultant shall be consulted during the design of these facilities in order to ensure the health of aquatic communities and minimize the risk of creating mosquito breeding areas.
(3) An outlet structure shall be designed to allow complete drainage of the pond for maintenance.
(4) The design of a retention basin shall include the determination of the proposed site's ability to support a viable permanent pool. The design shall take into account such factors as the available and required rate and quality of dry weather inflow, the stormwater inflow, seasonal and longer-term variations in groundwater table, and impacts of potential pollutant loadings.
(5) Sediment storage volume equal to at least 20% of the volume of the permanent pool shall be provided.
(6) A sediment forebay with a hardened bottom shall be provided at each inlet into the retention basin. The forebay storage capacity shall, at a minimum, be 10% of the permanent pool storage. The forebay shall be designed to allow for access by maintenance equipment for periodic cleaning. A permanent concrete cleanout maker shall be installed in the forebay to indicate the level where 25% for the forebay storage has been used.
(7) Emergency spillways shall be sized and located to permit the safe passage of stormwater flows from an unattenuated, 100-year, post-development storm with one foot of freeboard. The maximum velocities in vegetated spillways excavated in otherwise undisturbed soil shall be analyzed based upon the velocity of peak flow in the emergency spillway during an assumed clogged primary outlet condition. Where maximum velocities exceed design standards contained in the Engineering Field Manual for Conservation Practices (USDA, SCS, July 1984), suitable lining shall be provided. All emergency spillways placed on fill materials shall be lined. Lining for emergency spillways shall incorporate native colors and materials where possible, including mono slab revetments, grass pavers, riprap and native stone.
(8) Basin and pond embankments must be designed by a professional engineer registered in the Commonwealth of Pennsylvania. The design must include an investigation of the subsurface conditions at the proposed embankment location to evaluate settlement potential, groundwater impacts, and the need for seepage controls. The submittal of a geotechnical report from a geotechnical engineer for any embankment over 10 feet in effective height or posing a significant hazard to downstream property or life is required. The selection of fill materials must be subject to approval of the design engineer. Fill must be free of frozen soil, rocks over six inches, sod, brush, stumps, tree roots, wood, or other perishable materials. Embankment fills less than 10 feet in fill height must be compacted using compaction methods that would reasonably guarantee that the fill density is at least 90% of the maximum density as determined by standard proctor (ASTM-698). All embankment fills more than 10 feet in fill height must be compacted to at least 90% of the maximum density as determined by standard proctor (ASTM-698) and must have their density verified by field density testing. A PADEP dam permit is required for embankments having a maximum depth of water, measured from the upstream toe of the dam to the top of the dam at maximum storage elevation, of greater than 15 feet; and/or for ponds having contributory drainage area of greater than 100 acres; and/or for impoundments of greater than 50 acre-feet.
(9) The embankment's interior and exterior slopes may not be steeper than 3:1 (three horizontal to one vertical).
(10) The minimum embankment width shall be five feet for embankments less than three feet in height, 10 feet if the embankment is between 3.1 feet and 9.9 feet in height, and 15 feet if the embankment is higher than 10 feet.
(11) Existing ponds or permanent pool basins can be used for stormwater management, provided that it can be demonstrated that the ponds are structurally sound and meet the design requirements herein.
(12) Inlet structures and outlet structures shall be separated to the greatest extent possible in order to maximize the flow path through the retention basin.
(13) Retention basins shall be designed to provide a length-to-width ratio of at least 2L:1W as measured in plan view (for example, a ratio of 4L:1W is too narrow).
(14) The retention basin depth shall average three to six feet.
(15) A five-foot-wide bench around the pond perimeter is required at an elevation of one foot below the permanent water surface elevation. A structural or vegetative barrier may be required by the Town.
(16) Stabilization. Proper stabilization structures, including stilling basins, energy dissipaters, and channel lining, shall be constructed at the outlets of all retention basins and emergency spillways. The stabilization structures shall control water to: avoid erosion, reduce velocities of released water and direct water so that it does not interfere with downstream activities.
(17) Energy dissipaters shall be installed to prevent erosion and/or initiate sheet flow at points where pipes or drainageways discharge to or from basins. Energy dissipaters shall comply with criteria in Hydraulic Design of Energy Dissipaters for Culverts and Channels, HEC 14, FHWA, July 2006. Such facilities shall be both functional and harmonious with the surrounding environment; for example, native rock shall be used in constructing dissipaters where practical.
(18) Discharge points. The minimum distance between a proposed basin discharge point (including the energy dissipater, etc.) and a downstream property boundary shall in no case be less than 20 feet. Where there is discharge onto or through adjacent properties prior to release to a stream, designers shall demonstrate how downstream properties are to be protected. The Engineer may require that the setback distance be increased based upon factors such as topography, soil conditions, the size of structures, the location of structures, and discharge rates. A drainage easement may also be required.
(19) Outlet structures. Outlet structures shall meet the following specifications:
A. To minimize clogging and to facilitate cleaning and inspecting, outlet pipes shall have an internal diameter of at least 15 inches and a minimum grade of 1%.
B. Bentonite plugs shall be provided on all outlet pipes within a constructed berm.
C. All principal outlet structures shall be built using reinforced concrete with watertight construction joints.
D. The use of architecturally treated concrete, stucco, painted surface or stone facade treatment shall be considered for enhancing the outlet structure. Such facilities shall be both functional and harmonious in design with the surrounding environment.
E. Outlet pipes shall be constructed of reinforced concrete with rubber gaskets in conformance with AASHTO M170, M198 and M207, or smooth interior HDPE pipe in conformance with AASHTO M252 or M294.
F. Basin outlet structures shall have childproof, nonclogging trash racks overall design openings exceeding 12 inches in diameter except those openings designed to carry perennial stream flows. Periodic cleaning of debris from trash racks shall be included in the operation and maintenance plan.
G. Anti-vortex devices, consisting of a thin vertical plate normal to the basin berm, shall be provided at the top of all circular risers or standpipes.
(20) An easement 25 feet in width must be provided around the top perimeter of all retention facilities. This easement shall remain clear of any structures, sheds, retaining walls, swing sets, stored debris, etc. The entire twenty-five-foot easement, unless otherwise approved by the Town, must remain on the applicant's property.
(21) All detention facilities shall be provided with an access road (with a legal easement) for maintenance purposes. The design criteria for such access roads shall be as follows:
A. Access roads shall be a minimum of 10 feet wide and have a maximum grade of 15%.
B. Access must be provided from a public street to the berm of the facility so that equipment can obtain access to the outlet control works without entering the water impoundment area.
C. Access roads with gradients of 3% or less are permitted to be constructed with a stabilized base material and natural surface or equal as approved by the Town.
D. Access roads with gradients of 10% or less are permitted to be constructed with a stabilized base material and bituminous seal coat surface in accordance with PennDOT Publication 408, Section 470, or equal as approved by the Town.
E. A permanent easement must be provided for the access roadway from the public right-of-way to the stormwater detention facility. This easement shall be a minimum of 25 feet in width.
F. Access roads with gradients exceeding 10% shall be constructed with full depth bituminous pavement or concrete surfacing as approved by the Town.
G. Where deemed necessary by the Town, a permanent gate shall be provided for the access roadway. The design for the gate must be submitted to and approved by the Town.
(e) Detention basins.
(1) The landscape standards of §
913.17 shall apply.
(2) The maximum interior and exterior side slopes shall not exceed three horizontal to one vertical (3H:1V). The minimum required slope for the basin bottom is 2%. A level bottom is acceptable, provided that the designer demonstrates to the Town's satisfaction that the basin bottom will be landscaped with appropriate wetland vegetation pursuant to §
913.17. In addition, detention basins of sufficient size and slope may serve other functions as well, including recreational uses, which do not hinder or conflict with the function of the detention basin.
(3) Inlet structures. The inlet pipe invert into a basin shall be set above the one-year quality storm elevation or a minimum of six inches above the basin floor or lining so that the pipe can adequately drain after rainstorms. Inlets shall discharge into areas of the basin that slope toward the outlet structure.
(4) Inlet structures and outlet structures shall be separated to the greatest extent possible in order to maximize the flow path through the retention basin.
(5) Low-flow channels. Low-flow channels constructed of concrete or asphalt are not permitted. Where low-flow channels are necessary, they shall be composed of a natural or bioengineered material. Low-flow channels shall be designed to promote water quality and slow the rate of flow through the basin. Low-flow channels may also be designed to infiltrate where practical. The minimum slope of a low-flow channel shall be 1%.
(6) Outlet structures. Outlet structures shall meet the following specifications:
A. To minimize clogging and to facilitate cleaning and inspection, outlet pipes shall have an internal diameter of at least 15 inches and a minimum grade of 1%.
B. Bentonite plugs shall be provided on all outlet pipes within a constructed berm.
C. All principal outlet structures shall be built using reinforced concrete with watertight construction joints.
D. The use of architecturally treated concrete, stucco, painted surface or stone facade treatment shall be considered for enhancing the outlet structure. Such facilities shall be both functional and harmonious in design with the surrounding environment.
E. Outlet pipes shall be constructed of reinforced concrete with rubber gaskets in conformance with AASHTO M170, M198 and M207, or smooth interior HDPE pipe in conformance with AASHTO M252 or M294.
F. Energy-dissipation facilities that convert concentrated flow to uniform shallow sheet flow shall be used where appropriate.
G. Basin outlet structures shall have childproof, nonclogging trash racks overall design opening exceeding 12 inches in diameter except those openings designed to carry perennial stream flows.
H. Anti-vortex devices, consisting of a thin vertical plate normal to the basin berm, shall be provided at the top of all circular risers or standpipes.
(7) Emergency spillways shall be sized and located to permit the safe passage of stormwater flows from an unattenuated, 100-year, post-development storm with one foot of freeboard. The maximum velocities in vegetated spillways excavated in otherwise undisturbed soil shall be analyzed based upon the velocity of peak flow in the emergency spillway during an assumed clogged primary outlet condition. Where maximum velocities exceed design standards contained in the Engineering Field Manual for Conservation Practices (USDA, SCS, July 1984), suitable lining shall be provided. In general, emergency spillways should not be located in fill areas; all such facilities placed on fill materials shall be lined. Lining for emergency spillways shall incorporate native colors and materials where possible, including mono slab revetments, grass pavers, riprap, and native stone.
(8) Basin and pond embankments must be designed by a professional engineer registered in the Commonwealth of Pennsylvania. The design must include an investigation of the subsurface conditions at the proposed embankment location to evaluate settlement potential, groundwater impacts, and the need for seepage controls. The submittal of a geotechnical report from a geotechnical engineer for any embankment over 10 feet in effective height or posing a significant hazard to downstream property or life is required. The selection of fill materials must be subject to approval of the design engineer. Fill must be free of frozen soil, rocks over six inches, sod, brush, stumps, tree roots, wood, or other perishable materials. Embankment fills less than 10 feet in fill height must be compacted using compaction methods that would reasonably guarantee that the fill density is at least 90% of the maximum density as determined by standard proctor (ASTM-698). All embankment fills more than 10 feet in fill height must be compacted to at least 90% of the maximum density as determined by standard proctor (ASTM-698) and must have their density verified by field density testing. A PADEP dam permit is required for embankments having a maximum depth of water, measured from the upstream toe of the dam to the top of the dam at maximum storage elevation, of greater than 15 feet; and/or for ponds having contributory drainage area of greater than 100 acres; and/or for impoundments of greater than 50 acre-feet.
(9) Except where special erosion-protection measures are provided, all disturbed areas shall be graded evenly, topped with four inches of topsoil, fertilized, seeded, and mulched by methods approved by the Town. Seed mixes including crown vetch shall not be permitted.
(10) The minimum embankment width shall be five feet for embankments less than three feet in height, 10 feet if the embankment is between 3.1 feet and 9.9 feet in height and 15 feet if the embankment is higher than 10 feet.
(11) A structural or vegetative barrier may be required by the Town.
(12) Energy dissipaters shall be installed to prevent erosion and/or initiate sheet flow at points where pipes or drainageways discharge to or from basins. Level spreaders shall be used only where the maximum slope between the discharge point and the waterway does not exceed 5%. Energy dissipaters shall comply with criteria in Hydraulic Design of Energy Dissipaters for Culverts and Channels, HEC 14, FHWA, July 2006. Such facilities shall be both functional and attractive; for example, native rock shall be used in constructing dissipaters where practical.
(13) Stabilization. Proper stabilization structures, including stilling basins, energy dissipaters, and channel lining, shall be constructed at the outlets of all basins and emergency spillways. The stabilization structures shall control water to avoid erosion, reduce velocities of released water and direct water so that it does not interfere with downstream activities.
(14) Discharge points. The minimum distance between a proposed basin discharge point (including the energy dissipater, etc.) and a downstream property boundary shall in no case be less than 20 feet. Where there is discharge onto or through adjacent properties prior to release to a stream, designers shall demonstrate how downstream properties are to be protected. The Engineer may require that the setback distance be increased based upon factors such as topography, soil conditions, the size of structures, the location of structures, and discharge rates. A drainage easement may also be required.
(15) A sediment forebay with a hardened bottom shall be provided at each inlet into the detention basin. The forebay storage capacity shall at minimum be 10% of the permanent pool storage. The forebay shall be designed to allow for access by maintenance equipment for periodic cleaning.
(16) A private easement, 25 feet in width, must be provided around the top perimeter of all detention facilities. This easement shall remain clear of any structures, sheds, retaining walls, swing sets, stored debris, etc. The entire twenty-five-foot easement must remain on the applicant's property.
(17) All detention facilities shall be provided with an access road (with a legal easement) for maintenance purposes. The design criteria for such access roads shall be as follows:
A. Access roads shall be a minimum of 10 feet wide and have a maximum grade of 15%.
B. Access must be provided from a public street to the berm of the facility so that equipment can obtain access to the outlet control works without entering the water impoundment area.
C. Access roads with gradients of 3% or less are permitted to be constructed with a stabilized base material and natural surface, or equal as approved by the Town.
D. Access roads with gradients of 10% or less are permitted to be constructed with a stabilized base material and bituminous seal coat surface in accordance with PennDOT Publication 408, Section 470, or equal as approved by the Town.
E. A permanent easement must be provided for the access roadway from the public right-of-way to the stormwater detention facility. This easement shall be a minimum of 25 feet in width.
F. Access roads with gradients exceeding 10% shall be constructed with full depth bituminous pavement or concrete surfacing as approved by the Town.
G. Where deemed necessary by the Town, a permanent gate shall be provided for the access roadway. The design for the gate must be submitted to and approved by the Town.
(18) The volume and rate control capacities must drain in a period between 24 and 72 hours after the design storm.
(f) Conveyance systems (open channels, drainageways, and storm sewers).
(1) Applicants are encouraged to design conveyance systems that encourage infiltration and improve water quality wherever practicable.
(2) All conveyance systems shall convey stormwater to the nearest established stream channel as approved by the Engineer or storm sewer system.
(3) All conveyance systems shall have the appropriate erosion and/or energy-dissipation controls installed.
(4) Conveyance systems should not be installed parallel and near the top or bottom of major embankments to avoid the possibility of slope failure.
(5) Wherever conveyance channels are necessary, drainage shall be maintained by an open channel with landscaped banks designed to carry the 100-year stormwater runoff from upstream contributory areas. The Engineer may increase the design storm, as conditions require. All open channels shall be designed with one foot of freeboard above the design water surface elevation of the design runoff condition.
(6) Flood relief channels shall be provided and designed to convey the runoff from the 100-year, twenty-four-hour storm, such that a positive discharge of this runoff to an adequate receiving stream or conveyance system occurs without allowing this runoff to encroach upon other properties.
(7) Storm sewers and their appurtenant facilities shall be designed to convey the runoff from the 100-year storm. At no time shall the hydraulic grade line or energy grade line exceed the top of any inlet or manhole. Supporting calculations to document compliance with this requirement must be provided to the Engineer for review and approval.
(8) All storm inlets, manholes, endwalls, and headwalls shall be constructed in accordance with the Town Standard Specifications, Design Standards, and Details (latest edition).
(9) Storm inlets shall be placed at all street intersections and should be placed on the tangent and not the curved portions of any street. If possible, inlets shall be placed at lot lines to avoid potential conflicts with driveways.
(10) Storm inlets which are deeper than five feet in depth shall have ladder bars installed.
(11) A subarea drainage area map delineating the area draining to each inlet point of the storm sewer system is required to be part of the stormwater management plan.
(12) All storm sewer pipe proposed for public dedication, either to the Town or a homeowners' association, shall be greater than or equal to 15 inches in diameter.
(13) All storm sewer pipe proposed for public dedication under the cartway must be constructed of a minimum Class III reinforced concrete pipe (RCP) or as approved by the Town.
(14) No corrugated metal pipe may be used for storm sewers to be dedicated to the Town or a homeowners' association.
(15) The minimum grade on any storm sewer pipe shall be 1%, unless otherwise approved by the Engineer.
(16) Concrete anchors, per the Town Standard Specifications, Design Standards, and Details (latest edition), shall be required where the storm sewer pipe slope exceeds 20%.
(17) Manholes and/or inlets shall not be spaced more than 300 feet apart for pipe sizes up to 24 inches in diameter and not more than 450 feet apart for larger pipe sizes. Inlet capacity for inlets in paved or other impervious areas shall be based on the design standards provided by the latest edition of PennDOT Publication 584 and 13M. If acceptable information is not available, inlets in nonponding areas shall be designed for a maximum capacity of four cubic feet per second (cfs). When ponding occurs, inlet capacity shall be based on accepted engineering design practices.
(18) Where drainage swales are used in lieu of, or in addition to, storm sewers, they shall be designed to carry the required runoff without erosion and in a manner not detrimental to the properties they cross. Drainage swales shall provide a minimum grade of 2% but shall not exceed a grade of 9%. Drainage swales used strictly for conveyance are not the same as open vegetated channels. Design standards for open vegetated channels are provided under §
913.16(c) of this article.
(19) On streets that must contain curbing, storm sewers shall be placed in front of the curbing. To the greatest extent possible, storm sewers shall not be placed directly under curbing. At curbed street intersections, storm inlets shall be placed in the tangent section of the road.
(20) Use of grassed swales or open vegetated swales in lieu of curbing to convey, infiltrate and/or treat stormwater runoff from roadways is encouraged. Inlets shall be placed at the center of the shoulder swale draining the street and shall be located no closer than four feet from the edge of the cartway.
(21) Roof drains and sump pumps shall discharge to infiltration or vegetated BMPs where feasible.
(22) The developers shall obtain or grant a minimum twenty-foot-wide, private drainage easement over all storm sewers, drainage swales, channels, etc., that are a component of the stormwater management system when located within undedicated land. All permanent detention basins and/or other stormwater management facilities providing stormwater control for other than a single residential lot shall be located within a defined, private drainage easement that allows proper legal access and maintenance vehicle access.
(23) No property owner shall obstruct or alter the flow, location or carrying capacity of a stream, channel, or drainage swale to the detriment of any other property owner, whether upstream or downstream. All subdivision and/or land development plans containing streams, channels, drainage swales, storm sewers or other conveyance systems that cross property boundaries, existing or proposed, or whose discharge crosses such boundaries shall contain a note stating the above.
(24) Water quality inlets and/or bioretention areas. Storm drainage systems that collect runoff from parking areas and/or loading areas exceeding 10,000 square feet of impervious coverage and discharge to stormwater management systems, including surface or subsurface infiltration systems, shall have a minimum of one water quality inlet or bioretention area per each acre of drainage area. The purpose of water quality inlets is to remove oil, grease, and heavy particulates or total suspended solids, hydrocarbons, and other floating substances from stormwater runoff. Methods other than water quality inlets or bioretention areas may be permitted if the applicant demonstrates to the Town's satisfaction that any such alternative will be as effective and as easily maintained. Periodic cleaning of these systems shall be addressed in the operation and maintenance plan submitted to the Town. All bioretention areas should be designed as per the guidelines set forth in the PA Stormwater BMP Manual.
(g) Underground detention facilities.
(1) Underground detention tanks shall utilize the largest practicable pipe diameter in order to provide ease of access and maintenance.
(2) Design measures must be implemented to prevent pipe flotation and allow for visual inspection capabilities, adequate pipe ventilation, and access maintenance.
(3) Underground facilities shall be designed parallel to existing and/or proposed contours.
(4) The underground facilities shall be designed to include overflow controls able to pass the unattenuated 100-year peak storm without overtopping the access point.
(5) A minimum forty-eight-inch diameter manhole with steps must be provided at either end of the facility and at all terminal ends and junctions for maintenance purposes. A minimum of two accesses must be provided.
(6) Maximum life expectancy of the underground system shall also be a design consideration for pipe material specifications. The use of corrugated metal pipe (CMP) for underground facilities proposed for ownership and maintenance by the Town is prohibited.
(7) For underground rock sumps, refer to Appendix F of this article.
(h) All other stormwater management BMPs not discussed as part of this article shall adhere to the design requirements listed as part of the PA Stormwater BMP Manual.