Township of Manor, PA Storm Drain Manual for New Subdivisions

The importance of properly designed drainage from an economic, safety and public relations standpoint warrants a hydrologic analysis. Requirements for submittals of plans and calculations of proposed facilities are outlined in the following sections. Calculations must include an investigation of existing drainage facilities downstream of the project to insure that they are capable of accepting the additional runoff without causing flooding and erosion.

The basic concept of the stormwater management policy is to insure that downstream property owners, watercourses, channels or conducts are not adversely affected by an increase in stormwater runoff. Therefore, stormwater runoff from any development, during and after construction, shall be no greater than that flow resulting from the same storm event occurring over the site of the proposed development with the land in its existing, undeveloped condition.

A comparison analysis of the change in runoff shall be provided in the calculations.

All increases in stormwater runoff resulting from a proposed development shall be detained on the development site under predetermined and controlled conditions with the rate of drainage therefrom regulated by appropriately installed devices. Methods of detention or flow-delay devices may include but not be limited to the following:

Wet or dry ponds and detention basins;

Roof storage and increased roof roughness;

Parking lot retention;

Porous pavements, grassed channels and vegetated strips;

(e)

Cisterns and underground reservoirs;

(f)

Increasing the roughness coefficients on the development's surface area;

(g)

Decrease percentage of impervious area.

(5)

The use of other detention methods which prove to meet the objectives and intent of this chapter in accordance with the regulations and standards set forth herein will be permitted subsequent to the approval of the Township Engineer. Various possible combinations of methods may be evaluated on their particular merit for the type and location of development.

(6)

Storm sewer systems within a development shall be designed to handle the peak rate of runoff from a fifty-year frequency storm. Wherever the provisions of federal and state laws impose a greater design frequency, particularly in areas where drainage systems may cross highways, they shall prevail.

(7)

All stormwater retention/detention facilities shall be designed on the basis of providing adequate control for all storm frequencies up to and including the fifty-year storm. All designs shall provide emergency overflow facilities for the one-hundred-year storm, unless positive measures are installed to control the inflow so as not to exceed the safe capacity of the retention/detention facility.

(8)

The retention volume required shall be that necessary to handle runoff of a fifty-year storm from the development, less that volume discharged at the approved release rate.

(9)

The approved peak release rate of stormwater from all retention/detention facilities for any storm event shall be that which was experienced prior to development for the same storm event up to and including the fifty-year storm.

(10)

Stormwater control systems may be planned and constructed in coordination by two or more developments, so long as they are in compliance with the applicable provisions of this chapter.

(11)

All calculations and design parameters shall be subject to the review and approval of the Township Engineer, whose decision in matters involving engineering judgment shall be final.

(12)

In the design of storm drainage facilities, special consideration must be given to adjacent developed or undeveloped properties. In no case may a change be made in the existing topography which would:

Result in a slope of more than 10% within 20 feet of a property line.

Alter the existing drainage or topography in a way so as to adversely affect adjoining properties.

(13)

In no case may any slope exceed the normal angle of slippage of the material involved. All slopes must be protected against erosion.

Other approvals.

Designers are cautioned that the requirements contained herein are only minimum standards established for storm drainage approval by Manor Township. Compliance with this manual and subsequent approval by Manor Township does not preclude the developer's full responsibility in meeting any and all federal, state or county regulations as may be applicable.

The storm drainage system design should be coordinated with the Sediment and Erosion Control Plan for the project; however, approval of the storm drainage plan does not eliminate any requirements for an approved Sediment and Erosion Control Plan.

§ 371-2 Design.

[Amended 10-1-1979 by Ord. No. 6-79; 10-2-1982 by Ord. No. 3-82]

Reference materials. The reference materials to be used with this section are as follows:

"PennDOT Design Manual," Part 2, Chapter 12.

"Design Charts for Open-Channel Flow," U.S. Department of Commerce - Bureau of Public Roads.

"Hydraulic Charts for the Selection of Highway Culverts," Hydraulic Engineering Circular No. 5, U.S. Department of Commerce - Bureau of Public Roads.

"Design of Roadside Drainage Channels," Hydraulic Design Series No. 4, U.S. Department of Commerce - Bureau of Public Roads.

(5)

"Capacity Charts for the Hydraulic Design of Highway Culverts," Hydraulic Engineering Circular No. 10, U.S. Department of Commerce - Bureau of Public Roads.

Maximum expected discharge.

The maximum expected discharge (MED) may be defined as the maximum expected quantity of water, created by the design storm, arriving at a particular location (inlet, ditch, etc.).

The design storm is a selected intensity of rainfall, expressed in inches per hour, which tends to occur once during a specified period of years.

The maximum expected discharge from drainage areas less than 1 1/2 square miles shall be determined by the use of the Rational Equation. For larger drainage areas, see § 371-1C.

The Rational Equation is as follows:

Q = CIA

Where:
	Q	=	Maximum expected discharge in cubic feet per second.
	C	=	Runoff factor expressed as a percent of the total water falling on an area.
	I	=	The rate of rainfall for the time of concentration of the drainage area in inches per hour for a given storm frequency. A fifty-year storm frequency shall be used.
	A	=	The drainage area expressed in acres.

The above equation assumes that one inch of rainfall falling on one acre of land falls at the rate of one cubic foot per second. Thus, the total quantity of water falling on an area is represented by IA.

Runoff factor ("C").

It is necessary to adjust the total quantity of water falling on an area (IA) because a certain percentage of the water is dissipated by evaporation, transpiration, percolation, ponding, and physical characteristics such as sinkholes. Therefore, the runoff factor "C" is introduced into the Rational Equation to account for the dissipated water.

Suggested runoff factors for various types of drainage areas are presented in Table A at the end of this manual.

Design engineers shall determine "C" factors from field inspection of area and consideration of type of soil and average slopes of tributary areas. "C" factors shall represent a weighted average of the areas covered by the classification shown in Table A.[1]

Editor's Note: Table A is included in an attachment to this chapter.

Consideration should be given to future land use changes in the drainage area, including possible reclamation of land in areas where special situations, such as sinkholes, exist.

Rainfall intensity ("I").

Rainfall intensity shall be determined from Figure 1.[2] This curve indicates maximum rainfall intensities for storm durations (times of concentration, computed as described below) from five minutes to 24 hours, occurring with various frequencies.

Editor's Note: Figure 1 is included in an attachment to this chapter.

Time of concentration is defined as the time required for water to flow from the most remote part of the drainage area to the point under consideration and is the combined time of overland flow and flow in drains, swales, gutters and ditches.

Overland flow is sheet flow across lawns, graded areas, fields, etc. See Table B for recommended average velocities of overland flow.[3]

Editor's Note: Table B is included in an attachment to this chapter.

Velocity of flow in drains, swales, gutters and ditches shall be determined by the Manning Equation as discussed under Subsection C, Capacity of drainage facilities.

The time of concentration shall be calculated by the relationship:

Time =

Distance

Velocity

and shall be considered as representing the duration of storm. In no case shall a storm duration of less than five minutes be used.

Area ("A").

The extent of the drainage area may be determined from the following:

Photogrammetric plans.

Roadway design plans.

[c]

Field observations.

[d]

USGS maps.

The highest order of information available and practical shall be used.

Care should be taken to assure that all areas delivering runoff to the point under consideration shall be included and that physical obstructions, such as existing facilities with inadequate capacity inhibiting the delivery of runoff, shall be considered.

Capacity of drainage facilities.

The previous section has established a criteria for determining how much water is expected to arrive at a particular location (MED). This section is primarily concerned with the conveyance of the water arriving at that location.

It is necessary that the drainage facilities assisting in removal of water have adequate capacity to do so. Those facilities under consideration may be classified as follows:

Curbed sections;

Inlets;

Storm pipes;

Culverts;

Open channels.

The capacity of the drainage facilities is measured in terms of discharge and may be determined by the equation of continuity:

Q = AV

Where:
	Q	=	Discharge of water in cubic feet per second. A drainage facility at a particular location shall hydraulically and economically accommodate the maximum expected discharge (MED) for the location.
	A	=	The net effective area in square feet provided by the drainage facility. By "net effective area" is meant that cross-sectional area of the facility which may be used to carry water. It may not be desirable that the entire cross-sectional area of the drainage facility be utilized to carry water.
	V	=	The velocity of the water in feet per second. The velocity shall generally be determined by Manning's Equation.

Manning's Equation is as follows:

V =

1.486

R^2/3

S^1/2

Where:
	V	=	Velocity in feet per second.
	R	=	Hydraulic radius in feet = the net effective area (A) divided by the wetted perimeter (W.P.):

R =

W.P.

The wetted perimeter is the lineal feet of the drainage facility cross section which is wetted by the water.
S	=	Slope of energy line in feet per foot. For approximation, the invert slope may be used.
n	=	The roughness coefficient. Acceptable roughness coefficients are presented in Table C.[4]

Editor's Note: Table C is included in an attachment to this chapter.

Additional design criteria for specific drainage facilities are presented as follows:

Curbed sections.

The maximum encroachment of water on the roadway pavement shall not exceed half of a through traffic lane or one inch less than the depth of curb.

Inlets shall be provided to control the encroachment of water on the pavement.

Inlets.

General.

All inlets shall be in accordance with the latest edition of the PennDOT "Standards for Roadway Construction," except that only reinforced precast or cast-in-place reinforced concrete inlet boxes will be allowed. No brick masonry inlets will be accepted.

Three basic types of inlets, namely, Types C, M and S, are included in the above standards. Each type of inlet is suited for a particular situation. Type C inlet is designated for installation in nonmountable curbs. Type M inlet is designated for installation in mountable curbs and Type S inlet is designated for installation in swale or ditch areas. Inlet capacities for each specific type of inlet under various conditions are specified in the tables and figures as described below.

Type C inlet or Type M inlet. The capacities of Type C inlet or Type M inlet (mountable curb) on a continuous grade are presented in Table D for a 100% efficiency and in Figure 2 through Figure 5 for various percents of efficiency. The efficiency of an inlet is defined as (Q₂/Q₁) x 100%, where Q₁ is the channel flow in cfs and Q₂ is the rate of flow, in cfs, intercepted by the inlet gratings. The capacities for these inlets under sump conditions are indicated on Table E.[5]

Editor's Note: Table E is included in an attachment to this chapter.

Type S inlet.

The capacity of Type S inlets on a continuous grade is presented in Table F.[6] The capacity for this inlet under sump conditions is indicated on Figure 6 and Figure 7.[7]

[6]

Editor's Note: Table F is included in an attachment to this chapter.

[7]

Editor's Note: Figures 6 and 7 are included in an attachment to this chapter.

For installation of Type S inlet on continuous grade in swale areas, a drainage dike with side slope 8:1 or flatter (six-inch minimum height and one-foot maximum height) shall generally be placed below the inlet to achieve maximum capacity.

[c]

A lightweight grate may be specified for Type S inlets, provided that the inlet is located in a non-traffic area. The inlet that will accommodate the lightweight grate shall be designated with the suffix "LW," such as Type S-LW inlet.

Capacity and spacing.

If the capacity of an inlet under a specific condition is not included in the tables or figures as referred to above, it is generally satisfactory to use the value specified for the nearest condition.

Inlets shall be constructed in all sumps. Also, all street intersections receiving flow from curbed sections shall be protected by inlets.

[c]

On curbed sections immediately adjacent to structures, inlets shall be provided on each side of all structures having spans of 20 feet or greater for grades less than 1%. An inlet shall also be placed at the low point of sag vertical curves on curbed sections.

[d]

If the capacity of the previously defined allowable waterway portion of a curbed section exceeds the inlet capacities, the inlet capacities shall govern the spacing of inlets. If the capacity of the allowable waterway portion of a curbed section is less than the inlet capacities, then the capacity of this portion of the curbed section shall govern the spacing of inlets.

[e]

For curbed sections on a continuous grade, if analysis of inlet capacities based on a 100% efficiency has resulted in a spacing of less than 100 feet, then consideration shall be given to re-spacing the inlets by allowing channel flow to bypass the inlets to achieve economical effects provided that the maximum encroachment of water on the roadway pavement shall not exceed half a through traffic lane or one inch less than the depth of curb. Inlet spacing on curbed sections shall not exceed 450 feet.

[f]

Inlet spacing may generally be determined from the following formula giving due consideration to the percentage of water bypassing the inlet and, on curbed sections, the permissible encroachment of water on the roadway pavement.

L =

L = 43,560 Q

CIW

Where:
	L	=	Inlet spacing in feet.
	Q	=	Discharge capacity of the drainage facility (inlet, swale, curb sections, etc.) with the least capacity.
	C	=	Runoff factor.
	I	=	Rainfall intensity, inches per hour.
	W	=	Average width of contributing area.

[g]

When there is a change in pipe size in an inlet, the elevation for the top of pipes should be the same or the smaller pipe higher. A minimum drop of two inches should be provided in the inlet between the lowest inlet pipe invert elevation and the outlet pipe invert elevation. Inlet boxes may have to be modified to accommodate large pipe sizes. (Modified Type I and Type II as detailed in the PennDOT "Standards for Roadway Construction.")

Storm pipes.

In new subdivisions, storm drains shall normally be installed at the center line of the street. Storm drains shall be installed within the pavement area (no less than six feet from the curb) wherever possible.

To facilitate the solution of Manning's Equation as applied to storm pipes, charts are presented in "Design Charts for Open-Channel Flow" prepared by the U.S. Department of Commerce, which permit a direct determination of the capacity of circular pipes.

Where headroom is restricted, equivalent pipe arches may be used in lieu of circular pipe. An acceptable procedure for selecting a pipe arch is to determine the required circular pipe size from the charts and, subsequently, to select the equivalent pipe arch.

The minimum diameter of storm pipe shall be 18 inches, except pipes under a twenty-five foot or greater fill shall not be less than 24 inches. The top of storm pipes shall be at least six inches below subgrade elevation, except cast-iron pipe, which may be within three inches. The size of a downstream storm pipe shall not be smaller than that of the upstream storm pipe. Longitudinal pipes may serve as combination storm sewer and foundation underdrain pipe.

Abrupt changes in direction or slope of pipe shall be avoided. Where such abrupt changes are required, an inlet or manhole shall be placed at the point of change. The minimum slope in a pipe shall not be less than 0.35%.

[6]

All pipe materials and types utilized at any particular location shall be in accordance with the PennDOT Design Manual, Part 2, Chapter 12, except that no alternate types need be specified.

[7]

A typical "Computation Table for Storm Sewer Design" form is indicated on Table G.[8] A completed copy of this form shall be included in the required final calculations.[9]

[8]

Editor's Note: Table G is included in an attachment to this chapter.

[9]

Editor's Note: Amended at time of adoption of Code (see Ch. 1, General Provisions, Art. I).

Culverts.

In all cases where drainage is picked up by means of a head wall, and inlet or outlet conditions control, the pipe shall be designed as a culvert. When a pipe is part of a storm sewer system and crosses the roadway, it shall be designed as a storm sewer with the same design storm as the remainder of the system.

The minimum diameter of culvert shall be 18 inches, except pipes under a twenty-five foot or greater fill shall not be less than 24 inches.

The procedure contained in Hydraulic Engineering Circulars No. 5 and No. 10 as prepared by the U.S. Department of Transportation, Federal Highway Administration, Washington, D.C. shall be used for the design of culverts. The allowable headwater should be determined by the specific entrance conditions and good engineering judgment.

Velocities at culvert outlets shall not exceed acceptable limits as defined below without providing erosion protection. The design is not complete until the possibility of accelerated erosion is eliminated. The first step is to check actual velocity against the allowable maximum water velocities as specified in Table H. Where channel scour is indicated, appropriate means for reducing velocity to safe levels or for protecting the channel shall be incorporated.

(e)

Open channels.

Open channels shall be so located as to change the stream alignment as little as possible. However, it shall generally be considered desirable to eliminate bends, to cross streets (and future streets) normal to the street and to eliminate stream channels running through the center of a property where location near or on a property line is feasible.

The most common types of open channels are triangular, trapezoidal, and rectangular. The trapezoidal shape is preferred due to its higher hydraulic efficiency. Triangular shapes require less right-of-way and are readily maintained with a grader. Rectangular shapes are generally used in rock areas. The maximum bank slope on earth channels shall be three horizontal to one vertical.

To facilitate the solution of Manning's Equation and the continuity equations as applied to open channels, charts are presented in "Design Charts for Open-Channel Flow."

Where the depth of design flow is slightly below critical depth, channels shall have freeboard adequate to cope with the effect of hydraulic jump. Open channels shall have one foot of freeboard to accommodate silting. Where no appreciable silt deposits will occur, this one-foot freeboard may be eliminated.

Transverse channels shall join parallel channels at an angle of approximately 30° with the parallel channel to minimize scour and sedimentation.

[6]

Table H lists maximum permissible velocities for various channel lining materials.[10] Where calculated velocities exceed those permissible for earth, channels shall be paved or riprapped. Protective linings for channels and streams can be very expensive. Therefore, a special effort should be made to develop the lowest-cost erosion protection, including maintenance, for the particular location.

[10]

Editor's Note: Table H is included in an attachment to this chapter.

(f)

Detention basins. Detention basins may be constructed to temporarily detain the stormwater runoff. When such basins are used, the following design principles shall be observed:

The maximum planned depth (without a permanent pool) shall not exceed five feet.

The approach slopes of the basin will conform as closely as possible to natural land contours. Erosion control measures shall be provided as well as devices or measures to insure public safety.

Levee side slopes shall not exceed 3:1.

Outlet control structures shall be designed as simply as possible and shall operate automatically; they shall be of a safe capacity and be designed to limit the discharge to that which would have occurred with the land in its existing condition, prior to development.

Emergency overflow facilities must be provided for the one-hundred-year storm, unless positive measures are installed to control the inflow so as not to exceed the safe capacity of the basin.

(g)

Wet bottom basins. Where part of a detention basin will contain a permanent pool of water, the following requirements shall apply:

The minimum normal depth of water before the introduction of stormwater shall be four feet.

For emergency purposes, cleaning or shoreline maintenance, facilities shall be provided or plans prepared for the use of auxiliary equipment to permit emptying and drainage.

Aeration facilities may be required, dependent on the quality of the influent and detention time.

The side slopes shall be a nonerosive material with a slope of 3:1 or flatter. There shall be a freeboard of 12 inches to 18 inches above the high-water elevation on all wet bottom basins. Alternate designs for side slopes may be considered under special circumstances where good engineering practice is demonstrated.

(h)

Dry bottom basins. Detention basins which will not contain a permanent pool of water shall comply with the following requirements:

Provisions must be incorporated to facilitate interior drainage, to include the provision of natural grades to outlet structures, longitudinal and transverse grades to perimeter drainage facilities, or the installation of subsurface drains.

These basins may be designed to serve secondary purposes for recreation, open space or other types of use which will not be adversely affected by occasional or intermittent flooding.

(i)

Rooftop storage. Detention storage requirements may be met in total or in part by detention on flat roofs. Details of such designs to be included in the building permit applications shall include the depth and volume of storage, details of outlet devices and down drains, elevations of overflow scuppers, design loadings for the roof structure and emergency overflow provisions. Direct connection of roof drains to sewers or streets will be prohibited.

(j)

Parking lot storage. Paved parking lots may be designed to provide temporary detention storage of stormwater on all or a portion of their surfaces. Parking lot ponding should be arranged so that pedestrians can reach their destinations without walking through ponded water. Outlets will be designed so as to slowly empty the stored waters, and depths of storage must be limited so as to prevent damage to parked vehicles. Parking lot storage may be used in those areas where the health, safety, and general welfare of the community will not be adversely affected.

(k)

Detention storage. All or a portion of the detention storage may also be provided in underground detention facilities such as cisterns and covered ponds.

§ 371-3 Approval of plans and calculations.

General instructions.

All plans and calculations for proposed storm drain systems shall be submitted to the Manor Township Board of Supervisors for review and approval. No submittal shall be considered approved until such time as written and duly authorized notification of same is received by the applicant. The form and content of required submittals are outlined in Subsections C and D.

All submittals shall contain the professional seal, signature and registration number of the registered engineer or surveyor responsible for the design.

Standard drafting practices:

Final contract drawings shall be prepared in ink or pencil or a combination of both on tracing cloth or good quality Mylar reproducible sheets.

A complete title block shall be shown on all drawings. Title blocks shall contain at least the following information:

Descriptive title of drawing.

Name of subdivision.

Designer, tracer and checker's initials and dates completed.

Designated space for signature and date of approving agency.

A revision block shall be provided on each sheet with space for all revision dates and nature of revision.

A complete description of all bench marks shall be shown, including location and elevation.

(5)

Each drawing shall be so oriented that the North arrow points toward the top or toward the left side of the sheet.

(6)

All drawings in the same project shall be cross-referenced.

Preliminary report. Prior to the preparation of final plans, two copies of a preliminary report shall be submitted for review. Reports shall generally contain the following information:

General description of the project.

Discussion of proposed work, as to the location, size and other pertinent data.

Recommendations and conclusions.

Supporting drawings, calculations and any other data necessary to support and depict the written conclusions. Drawings shall include a map of the entire drainage area showing the proposed storm drainage system in conjunction with existing drains. Calculations shall include runoff data and preliminary sizing of proposed drains, plus an investigation of the effect of the proposed construction on existing downstream facilities. Additional submittals of the preliminary report may be required, at the discretion of the Board of Supervisors, incorporating revisions and recommendations made in a previous review.

Final plans and calculations.

Following approval of the preliminary report, final storm drain drawings and calculations shall be prepared and two copies of same shall be submitted for review. Final drawings shall include, but not be limited to, the following information:

A location plan showing the names of streets and roads leading to the site and the distance to nearest municipalities.

A drainage area map showing entire drainage area with each tributary area lettered for reference to calculations and tabulation forms. The proposed drainage system shall be indicated schematically, complete with inlets, manholes and structures.

A plan and a profile of proposed system showing the following:

All property lines, right-of-way lines, lot numbers and front dimensions of lots.

All roads and streets with names, curblines, pavement widths and cross slopes, grades and curb radii.

All existing and proposed utilities completely labeled.

Elevation contour lines at five-foot vertical intervals on proposed finished ground.

Entire proposed storm drain system including inlets, manholes, pipes, ditches, etc., completely labeled as to type and size and with invert elevations and slopes shown. Location of all components shall be dimensioned from property lines.

North arrow on all plan views.

(e)

Appropriate scale shown as a bar scale.

Final calculations shall consist of a complete hydrologic and hydraulic analysis of all components of the proposed storm drainage system. Completed flow tabulation forms (see Table G) shall be included.[1]

Editor's Note: Table G is included in an attachment to this chapter.

All structural calculations and/or references to standard loading tables shall be shown. Where information pertinent to design, such as core borings, has been collected, this information shall also be submitted.

Following incorporation of review comments and approval by the Board of Supervisors, all original drawings and documents shall be presented for signature by a duly authorized representative of the Board. Such signature shall constitute final approval and all originals shall become the property of Manor Township.

§ 371-4 Runoff coefficients.

See Attachment 1 of this chapter.[1]

Editor's Note: Attachment 1 is included as an attachment to this chapter.

§ 371-5 Violations and penalties.

[Amended 2-19-1985 by Ord. No. 1-85; 9-6-1988 by Ord. No. 5-88[1]]

Any person who violates or permits a violation of this chapter shall, upon conviction in a summary proceeding brought before a Magisterial District Judge under the Pennsylvania Rules of Criminal Procedure, be guilty of a summary offense and shall be punishable by a fine of not more than $1,000, plus costs of prosecution. In default of payment thereof, the defendant may be sentenced to imprisonment for a term not exceeding 90 days. Each day or portion thereof that such violation continues or is permitted to continue shall constitute a separate offense, and each section of this chapter that is violated shall also constitute a separate offense.