PART 906 PRIVATE SEWAGE MOUND CODE : Sections Listing

TITLE 77: PUBLIC HEALTH
CHAPTER I: DEPARTMENT OF PUBLIC HEALTH
SUBCHAPTER r: WATER AND SEWAGE
PART 906 PRIVATE SEWAGE MOUND CODE


AUTHORITY: Implementing and authorized by the Private Sewage Disposal Licensing Act (Ill. Rev. Stat. 1987, ch. 111½, pars. 116.301 et seq.)

SOURCE: Adopted at 13 Ill. Reg. 12608, effective August 1, 1989)

 

Section 906.10  Applicability

 

a)         This Part is promulgated by the Illinois Department of Public Health in order to establish requirements for the design and construction of mounds in Illinois which are to be used as private sewage disposal systems. All such mounds must be constructed in accordance with the requirements of this Part.

 

b)         Plan approval must be obtained from the Department or local authority prior to beginning any construction of a mound system in accordance with Section 905.190 of the Private Sewage Disposal Code (77 Ill. Adm. Code 905).  All individuals who construct such systems must be licensed as a Private Sewage Disposal System Installation Contractor.

 

Section 906.20  Definitions

 

"Absorption Area" means the area of coarse aggregate in the absorption bed or trenches in a mound.

 

"Basal Area" means the area of natural soil under a mound which is effective in absorbing effluent.

 

"Depression" means an area that is sunk below its surroundings.

 

"Dosing" means the application of sewage under pressure to a sewage disposal system at constant intervals or in constant amounts per application.

 

"Drainageway" means a natural or artificial channel for the discharge of surface water through a given tract of land or region.

 

"Flood plain" means the land bordering a stream, built up of sediments from overflow of the stream and subject to inundation when the stream is at flood stage.

 

"Mound" means a soil absorption sewage treatment system that is elevated above the natural ground surface in a suitable fill material as defined in 906.40.

 

"Perched Water Table" means groundwater which is trapped above a normal water table by an impervious formation.

 

"Percolation Rate" means the downward movement of water through a saturated soil.

 

"Permeable Soil" means soil which has a percolation rate between 18 and 180 minutes.  (See Appendix A, Illustration G of the Private Sewage Disposal Code for meaning of percolation rate and percolation test procedure.)

 

"Shallow Permeable Soil" means pervious soil over creviced or porous bed rock, 5½ feet or less in thickness.

 

"Slowly Permeable Soil" means soil having a percolation rate of between 180 and 360 minutes.

 

Section 906.25  Incorporated Materials

 

a)         The following federal and state regulations, standards and statutes are incorporated or referenced in various sections of this Part.

 

1)         1986 Annual Book of ASTM Standards:

 

American Society for Testing and Materials

1916 Race Street

Philadelphia, PA 19103

 

2)         American Society for Testing and Materials (ASTM) required standards for approved plastic pipe and published by:

 

American Society for Testing and Materials

1916 Race Street

Philadelphia, PA  19103

 

b)         All incorporations by reference of federal regulations and the standards of nationally recognized organizations refer to the regulations and standards on the date specified and do not include any additions or deletions subsequent to the date specified.

 

c)         All materials incorporated by reference are available for inspection and copying at the Department's Central Office, Division of Environmental Health, 525 West Jefferson, Springfield, Illinois 62761.

 

Section 906.30  Soil and Site Requirements

 

In order to be suitable for mound construction, the site shall meet the following requirements and those listed in Appendix A, Exhibit A.

 

a)         Percolation Rates.  Percolation rates shall be used to determine the suitability of the site for accepting effluent.  Percolation tests shall be performed according to the procedure outlined in Appendix A, Illustration G of the Private Sewage Disposal Code (77 Ill. Adm. Code 905).  Excepting that, percolation tests shall be performed at a depth of 20-24 in. from the natural surface.  However, in cases where a more slowly permeable soil horizon is above this depth the percolation tests shall be conducted in the more slowly permeable soil horizon.  Those results shall be used in the design of the mound.  For shallow permeable soils over pervious bedrock, the percolation test shall be run at a depth of 12-18 in. below the natural surface.  For permeable soils with high water tables, the percolation test shall be run at a depth of 20-24 in. below the natural surface.

 

b)         Depth to Pervious Rock or Seasonal High Water Table.  There shall be a minimum of 24 in. of unsaturated soil between the soil surface and pervious bedrock or the seasonal high water table, including a perched water table, at the proposed mound site.  High water tables can be determined by direct observation or by soil mottling.  Occurrence of grey and red soil mottling patterns can be used to indicate periodic saturation with water.

 

c)         Rocky Soils.  If the soil contains 50% rock fragments or more by volume in the upper 24 in. of soil, the mound basal area shall be 25% larger than that normally required.

 

d)         Slopes.  The mound shall be placed upslope and not at the base of the slope of the existing ground.  On a site where there is a complex slope, (two directions), the mound shall be situated such that the liquid is not concentrated in one area downslope.  Upslope runoff shall be diverted around the mound.  For the more permeable soils where the percolation rate is 18-179 min., slopes shall not exceed 12%.  For tighter soils where the percolation rate is 180-360 min., slopes shall not exceed 6%.

 

e)         Flood Plains.  Construction of mound systems shall not be allowed in flood plains, drainage ways or depressions.

 

f)         Sites with Trees and Large Boulders.  Sites with large trees, numerous smaller trees or large boulders are unsuitable for the mound system.  If no other site is available, the trees shall be cut off at ground level, leaving the stumps.  An increase in mound basal area shall be required where stumps are involved, so that sufficient soil is available to accept the effluent.  The increase in mound area shall equal the surface area of the stumps on the mound site.

 

g)         Site Preparation

 

1)         Vegetation shall be cut and removed from the site prior to construction.  The site must then be plowed with a mold board plow 7-8 in. deep with the plowing done perpendicular to the slope.  Plowing shall not be done with the furrow running up and down the slope.  Chisel plowing may be used in place of mold board.  Roto tilling is prohibited.  However, roto tilling may be used to incorporate the vegetative cover in unstructured soil such as sand.

 

2)         Site preparation shall not take place when the soil is too wet.  The soil shall be considered too wet when a soil sample taken at a depth of 7-8 in. beneath the surface can be rolled between the palms of the hands into a continuous ribbon of soil.  If the soil crumbles, site preparation can then proceed.

 

3)         Once the site is plowed, all construction machinery and other vehicles shall be kept off the mound site.  The fill material shall be deposited on the site with a backhoe or pushed on from the side, using a track type tractor, keeping 6 in. of fill beneath the tracks.  At no time shall ruts be made in the plowed area.  The fill shall be placed immediately after site preparation to avoid the possibility of precipitation falling on the plowed area.

 

4)         All work shall be performed from the ends and upslope side, especially on fine textured soils.

 

Section 906.40  Fill Material

 

a)         Below Absorption Area

 

1)         A mound system shall be provided with a fill material beneath the absorption area (trenches or bed).  One of the following fill materials shall be used.

 

A)        FA-1

 

B)        FA-2

 

C)        FA-3

 

D)        FA-8

 

E)        FA-9

 

2)         These materials are classified and graded in accordance with Illinois Department of Transportation, Division of Highways specifications for fine aggregate.  These materials shall meet the gradation specifications as shown for these five fine aggregates in Appendix A, Exhibit B.

 

b)         Above the Absorption Area.  The cap (area above the bed or trenches) shall consist of a topsoil to allow plant growth.  Sands are not allowed since they drain rapidly and allow more infiltration of precipitation into the absorption area.  Topsoil shall be placed to a depth of 6 in. over the entire mound to promote good vegetation cover.  The cap soil shall be seeded and fertilized.

 

Section 906.50  Mound Design

 

a)         A mound system shall include a septic tank for pre-treatment of sewage.  The septic tank and piping between the septic tank and the pumping chamber shall conform to the applicable rules in the Private Sewage Disposal Code (77 Ill. Adm. Code 905).

 

b)         The design of the mound shall be based upon the expected daily waste water volume using the data contained in Appendix A, Illustration A, of the Private Sewage Disposal Code, (77 Ill. Adm. Code 905) and the soil percolation rate.  Mounds shall be sized such that they can accept the daily waste water flow without surface seepage, and the basal area, which is the natural soil area beneath the mound, shall be sufficiently large to conduct the effluent into the underlying topsoil.  The system shall also be designed to avoid encroachment of the water table into the mound.

 

c)         For homes having up to and including 4 bedrooms or for flows less than 800 gallons per day the mound shall be designed in accordance with 906.60. For homes with 5 or more bedrooms or for flows greater than or equal to 800 gallons the mound shall be designed in accordance with 906.70.

 

d)         Design of the Absorption Area

 

1)         Sizing the absorption area.  The size of the absorption area is dependent upon the daily waste water flow.  The design infiltration capacity of the fill material shall be 1.2 gal/ft2/day.

 

2)         Absorption Area Design

 

A)        System configuration.  The absorption area within the mound shall be constructed as trenches or beds.  An illustration of construction using trenches and bed is shown in Appendix A, Illustration A through D.  The location of the water table and soil permeability will dictate whether a trench or bed shall be used. In slowly permeable soils, two or three narrow parallel trenches shall be used instead of a bed.  Trench widths shall be between 24 and 48 inches. For permeable soils either a narrow rectangular bed or two or three narrow parallel trenches may be used.  Bed widths shall not be greater than 10 ft.

 

B)        On sloping sites, the trenches and beds shall be situated perpendicular to the slope in order to prevent the concentration of effluent into a small area as it moves laterally downslope.  Sufficient basal area shall be provided so all the effluent infiltrates into the natural soil before it reaches the toe of the mound.  With a trench system, the trench spacing shall be such that the effluent from an upslope trench shall be absorbed by the natural soil before reaching the area under the next trench downslope.

 

C)        The bottom of the absorption area within the bed and trenches shall be level and at the same elevation.

 

e)         Mound Dimensions

 

1)         Mound height.  The mound height shall consist of the fill depth (D & E), the trench or bed depth (F), and the cap and topsoil depth (G & H) as shown in Appendix A, Illustration A through D for trench and bed construction respectively.  A minimum of 1 foot of fill is required under the bed or trenches.  For sites where the soil depth is less than 3 feet over creviced bedrock, the fill depth (D) shall be a minimum of 2 feet.

 

2)         Bed or trench depth (F).  The depth of the bed or trenches shall be at least 10 inches.  A minimum of 6 in. of aggregate shall be placed beneath the distribution pipe.  Clean, ½-2 inch stone shall be used.  The use of soft limestone is prohibited.

 

3)         Cap and topsoil (H & G).  The depth of soil over the aggregate at the apex (H) shall be a minimum of 1.5 ft.  For a 3 parallel trench system, the depth shall be a minimum of 2 ft.  At the outer edge of the gravel the cap and topsoil shall be at least 1 ft. deep.  The cap shall be topsoil or finer textured subsoil.  A minimum of 6 inches of topsoil shall be placed over the entire mound.  The topsoil shall be seeded with grass seed to control erosion.

 

4)         Side and end slopes.  Side and end slopes shall be no steeper than one foot vertical rise in 3 feet horizontal.

 

f)         Basal Area

 

1)         The basal area is the natural soil-fill interface of the mound.  The basal area required shall be dependent upon the soil and site conditions. For level sites, the total basal area beneath the mound can be used.  For sloping sites the only basal area which may be considered for design is the area beneath and downslope of the bed or trenches (see Appendix A, Exhibit C).  The percolation rate of the natural soil shall determine the mound area required.  For the percolation rates shown the following design loading rates shall be used:

 

A)        60 min – 1.2 gal/ft2/day

 

B)        180 min – .74 gal/ft2/day

 

C)        360 min – .24 gal/ft2/day

 

2)         If sufficient basal area is not available for the given design and site conditions, additional fill shall be used to make the mound wider for a level site or the fill used to extend the downslope width on a slope site until sufficient area is available.

 

Section 906.60  Distribution System (for sewage flows of less than 800 gallons per day)

 

a)         Piping System.  The piping distribution system for the mound shall consist of a manifold pipe and small diameter laterals with perforations. The perforations shall be drilled at 30"-36" intervals along with the invert of the lateral.  Perforations shall be installed perpendicular to the pipe axis.  Perforation diameters shall be between 3/16" and ¼".  If the distance between the end of the lateral and the nearest perforation is greater than ½ the perforation spacing used, another hole shall be installed in or near the end cap of the lateral.  A typical distribution system of a mound is shown in Appendix A, Illustration E.  For a trench system, one lateral shall be required per trench; for a bed system, up to 3 laterals may be used.  Laterals shall extend to within 6 inches of the end of the bed or trench.  Lateral spacing shall be a maximum of 3 ft. for beds in small mounds only (1-4 bedroom sized system).  Pipe diameter will depend upon the length of bed or trenches.  The allowable lateral lengths for various size diameter pipes and various hole spacings are given in Appendix A, Exhibit D.  The system shall be designed and placed so that the laterals and manifold drain after every dosing.  If the mound is downslope of the pumping chamber, the manifold shall be on top of the laterals so the manifold drains, or cross-to-cross construction used.  For systems which are to treat a flow of more than 800 gallons per day, the manifold and lateral network must be designed in accordance with Section 906.70.  All piping shall be Schedule 40 Polyvinyl Chloride (ASTM Standard D1785/76) or Schedule 40 Acrylonitrile/Butadiene/Styrene (ASTM Standard D1527/77).

 

b)         Pumping System.  The components of the pumping system shall consist of the pumping chamber, pump, pump controls and alarm system as shown in Appendix A, Illustration F.  The dosing volume shall be ten times the total lateral pipe void volume or one-fourth the estimated daily sewage flow, whichever is greater.  Appendix A, Exhibit F lists the void volumes for various sizes of pipe.  The daily volume of sewage shall be determined using Appendix A, Illustration A of the Private Sewage Disposal Code (77 Ill. Adm. Code 905).

 

1)         Pumping Chamber Requirements.

 

A)        Pumping Chamber.  Appendix A, Illustration F gives a cross-section of a typical pumping chamber.  The volume shall be sufficient to provide the desired dosing volume, space for controls, space for setting the pump on a pedestal, and extra volume for a malfunction and flow-back after pump shuts off.  Appendix A, Exhibit G establishes pumping chamber sizes for the various sized systems.  Larger tanks may be used, but they may limit the flexibility of adjusting the desired dosing quantity.  Sufficient volume must be available to provide for the dose volume, pump pedestal and controls.

 

B)        The pumping chamber shall be waterproof.  Waterproofing shall consist of sealing all joints and coating the outside of the tanks.  The pumping chamber shall be filled with water after being installed and back filled to prevent the pumping chambers from floating out of position due to hydrostatic pressures, unless the tank is installed in dry soil.  A riser pipe shall extend at least 6 in. above the ground surface.  All electrical controls shall be mounted outside the tank.  The pump disconnect shall be accessible for easy pump removal in the event of pump failure.

 

2)         Pump Selection.  The pump shall be a submersible pump designed for corrosive liquids and shall be capable of maintaining at least 2 feet of head at the distal ends of the laterals.  The pump switch shall be controlled by a float in the pumping chamber, set so that the required dosing volume is discharged during each pumping cycle.  A check valve between the pump and the piping network manifold shall not be allowed.

 

3)         Pump and Alarm Control.  The control system for the pumping chamber shall consist of a control for operating the pump and an alarm system to detect when the system is malfunctioning.  Pump controls shall be selected which give flexibility in adjusting the on-off depth.  Example of acceptable controls are shown in Appendix A, Illustration F.  Pump controls shall be adjusted to pump the required dose of sewage plus the volume of sewage which flows back to the pumping chamber after shut-off.

 

4)         Electrical and Alarm System.  The alarm system shall consist of an audible and visual alarm in the home or facility building.  This system shall be on a circuit separate from the pump.  The electrical controls shall be placed outside the pumping chamber.

 

5)         Siphons.  Siphons can be designed where elevation exists between the mound and the siphon chamber.  However, the siphon shall be designed to deliver the same flow rate at the same head at the distribution system as a pump system.  The distribution system consisting of manifold and laterals shall be designed so that it will drain after each siphon.  This shall be accomplished by placing the manifold above the laterals.

 

Section 906.70  Distribution System (for sewage flows in excess of 800 gallons per day)

 

a)         Design criteria for laterals.

 

1)         The variation in discharge rates from the perforations in any lateral shall not exceed ten percent.

 

2)         The variation in discharge rates between the perforations of any two laterals shall not exceed 15%.

 

3)         The pressure at the distal ends of the lateral shall be at least 2.5 feet of water.

 

b)         Perforations.  The perforation requirements of this Section shall be used in place of those of Section 906.60.

 

1)         The perforations shall be spaced uniformly along the laterals and at an interval not to exceed 10 feet.

 

2)         Perforations shall be installed perpendicular to the centerline of the lateral and along the lateral invert.

 

3)         Perforation diameter shall be between ¼ and ⅝ inches.

 

4)         To facilitate the draining of laterals between dosing cycles, a perforation shall be installed at the distal end of each lateral near the crown of the pipe.

 

c)         Network Configuration

 

1)         The laterals shall be installed in seepage beds.  The lateral spacing shall equal the perforation spacing.  The perforations of adjacent laterals in the bed shall be staggered.

 

2)         Mounds employing multiple beds may be used.  Also, multiple mounds may be employed.  If bed elevations are not all equal, then this fact must be considered in the design of the pipe network in order to provide uniform dosing of effluent.

 

3)         Manifold-to-lateral connections shall be made using tee-to-tee construction, with the manifold below the laterals (see Appendix A, Illustration G).  If the design is such that the manifold does not drain between dosing cycles, then insulation or some other means shall be provided to prevent freezing.  In addition, provisions shall be made for manual draining of the manifold.

 

4)         Two separate distribution networks may be employed, with each network receiving alternate doses of effluent through the use of alternating pumps, valves, or siphons.

 

5)         Siphons or siphon breaks shall be used in networks where the low water level in the pumping chamber is above the lateral inverts.

 

d)         Pumping Chamber

 

1)         Dosing volume.  Dosing volume shall be determined by dividing the average daily sewage flow by the dosing frequency for the particular soil type, as is shown in Appendix A, Illustration H.  Dosing volume shall be at least five times the pipe volume of the network.  The dosing volume is the amount of liquid pumped or siphoned during each cycle minus the amount which drains back from the system after each dose.

 

2)         Reserve capacity.  If a single pump is used, a reserve capacity equal to one day's average sewage flow shall be provided.  A reserve capacity is not required if multiple pumps or siphons are used.

 

3)         A high water alarm switch shall be installed 2-3 inches above the pump or siphon activation level.  The switch shall be on a circuit separate from the pump controls.

 

4)         The pump or pumps shall be of a submersible type, designed for corrosive liquids.  The control switches shall be corrosion resistant.  All electrical contacts and relays shall be mounted outside the chamber. Provisions shall be made to prevent gases in the chamber from following the electrical conduits into the control box.



Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION A   Plan View of a Mound Utilizing Two Trenches as the Absorption Area

 

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION B   Cross-Section of a Mound Using Trenches for the Absorption Area

 

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION C   Plan View of a Mound Utilizing a Bed as the Absorption Area

 

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION D   Cross-Section of a Mound Using a Bed for the Absorption Area

 

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION E   Mound Distribution System

 

 

 


Mound Distribution System (continued)

 

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION F   Typical Pumping Chamber

 

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION G   Tee-To-Tee Lateral/Manifold Construction

 

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION H   Dosing Frequencies for Various Soil Textures

 

Soil Texture

Dosing Frequency

 

 

Sand

4 doses/day

Sandy loam

1 dose/day

Loam

Frequency not critical*

Silt loam; silty clay loam

1 dose/day*

Clay

Frequency not critical*

 

*Long-term resting provided by alternating fields may be desirable.

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.ILLUSTRATION I   Maximum Manifold Length (ft) for Various Manifold Diameters Given the Lateral Discharge Rate and Lateral Spacing

 

Lateral

Discharge Rate

 

Manifold

Diameter – 1¼"

 

Manifold

Diameter – 1½ "

 

Manifold

Diameter – 2"

 

 

 

End

Manifold

Central

Manifold

 

Lateral

Spacing (ft)

 

Lateral

Spacing (ft)

 

Lateral

Spacing (ft)

 

 

 

 

 

2

4

6

8

10

 

2

4

6

8

10

 

2

4

6

8

10

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

10

5

 

4

8

6

11

10

 

10

5

6

8

10

 

12

16

24

24

30

20

10

 

4

4

6

 

 

 

4

4

6

8

10

 

4

8

12

16

20

30

15

 

2

 

 

 

 

 

2

4

6

 

 

 

6

8

6

8

10

40

20

 

 

 

 

 

 

 

 

 

 

 

 

 

4

4

6

8

10

50

25

 

 

 

 

 

 

 

 

 

 

 

 

 

2

4

6

8

 

60

30

 

 

 

 

 

 

 

 

 

 

 

 

 

2

4

 

 

 

70

35

 

 

 

 

 

 

 

 

 

 

 

 

 

2

4

 

 

 

80

40

 

 

 

 

 

 

 

 

 

 

 

 

 

2

 

 

 

 

90

45

 

 

 

 

 

 

 

 

 

 

 

 

 

2

 

 

 

 

100

50

 

 

 

 

 

 

 

 

 

 

 

 

 

2

 

 

 

 

 

 

Lateral

Discharge Rate

 

Manifold

Diameter – 3"

 

Manifold

Diameter – 4 "

 

Manifold

Diameter – 6"

 

 

 

End

Manifold

Central

Manifold

 

Lateral

Spacing (ft)

 

Lateral

Spacing (ft)

 

Lateral

Spacing (ft)

 

 

 

 

 

2

4

6

8

10

 

2

4

6

8

10

 

2

4

6

8

10

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

10

5

 

24

40

48

56

70

 

42

64

84

96

110

 

84

136

174

206

240

20

10

 

16

24

30

32

40

 

26

40

54

64

70

 

54

84

108

128

150

30

15

 

12

16

24

24

30

 

20

28

36

48

50

 

42

64

84

96

110

40

20

 

10

12

18

16

20

 

16

24

30

32

40

 

34

52

66

80

90

50

25

 

8

12

12

16

20

 

14

20

24

32

40

 

30

44

60

72

80

60

30

 

6

8

12

16

20

 

12

16

24

24

30

 

26

40

48

64

70

70

35

 

6

8

12

8

10

 

10

16

18

24

30

 

24

36

48

56

60

80

40

 

6

8

6

8

10

 

10

12

18

16

20

 

22

32

42

48

60

90

45

 

4

8

6

8

10

 

8

12

18

16

20

 

20

28

42

48

50

100

50

 

4

4

6

8

10

 

8

12

12

16

20

 

18

28

36

40

50

110

55

 

4

4

6

8

10

 

8

12

12

16

20

 

16

24

36

40

40

120

60

 

4

4

6

8

10

 

6

8

12

16

10

 

16

24

30

32

40

130

65

 

4

4

6

8

10

 

6

8

12

16

10

 

14

24

30

32

40

140

70

 

2

4

6

8

 

 

6

8

12

8

10

 

14

20

24

32

40

150

75

 

2

4

6

 

 

 

6

8

12

8

10

 

14

20

24

32

30

160

80

 

2

4

6

 

 

 

6

8

6

8

10

 

12

20

24

32

30

170

85

 

2

4

6

 

 

 

4

8

6

8

10

 

12

20

24

24

30

180

90

 

2

4

 

 

 

 

4

8

6

8

10

 

12

16

24

24

30

190

95

 

2

4

 

 

 

 

4

8

6

8

10

 

12

16

18

24

30

200

100

 

2

4

 

 

 

 

4

4

6

8

10

 

10

16

18

24

30

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT A   Soil and Site Factors that Restrict Mound Systems

 

 

Soil Group

 

Slowly Permeable Soils

Permeable Soils With Pervious Bedrock

Permeable Soils With High Water Tables

Percolation rate a

180-360 min.

18-180 min.

18-180 min.

Depth to pervious rock

24 in.

24 in.

24 in.

Depth of high water tables

24 in.

24 in.

24 in.

Minimum depth to impermeable soil layer or rock strata

60 in.

60 in.

60 in.

Depth to 50% by volume rock fragments

24 in.

24 in.

24 in.

Slope

6%

12b

12% b

 

a     Percolation test depth at 24 in., 12 in., and 24 in., for slowly permeable, shallow soils and high water table soils, respectively, unless there is a more restrictive horizon above.  If perched water is at 24 in., test depth should be held to 16 in.

 

b     For percolation rate of 18-90 minutes max. slope is 12% and for 18-360 minutes, max. slope is 6%.


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT B   Fine Aggregate Gradations

 

Sieve Size

Percent Passing

Grad.

 

No.

No.

No.

No.

No.

No.

No.

No.

No.

No.

3/8

4

8

10

16

40

50

80

100

200

FA 1

100

97±3

 

 

65±20

 

16±13

 

5±5

 

FA 2

100

97±3

 

 

65±20

 

20±10

 

5±5

 

FA 3

100

97±3

 

80±15

 

50±20

 

25±15

 

3±3

FA 4

100

 

 

 

5±5

 

 

 

 

 

FA 5

100

92±8

 

 

 

 

 

 

20±20

15±15

FA 6

 

92±8

 

 

 

 

 

 

20±20

5±5

FA 7

 

100

 

97±3

 

75±15

 

35±10

 

3±3

FA 8

 

 

100

 

 

60±20

 

 

3±3

2±2

FA 9

 

 

100

 

 

 

20±15

 

5±5

 

FA 10

 

 

 

100

 

90±10

 

60±30

 

7±7

 

Horizontal Grade No. indicates the sieve sizes used to test the material sample.  FA numbers indicate the Illinois Department of Transportation fine aggregate sizes.

 

Numbers throughout the table such as 97 ± 3 mean that 97% of the sample, plus or minus 3% of the sample passed through the screen.

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT C   Downslope and Upslope Width Corrections for Mounds on Sloping Sites

 

 

 

Slope %

Downslope (I) Correction Factor

Upslope (J) Correction Factor

 

 

 

0

1.00

1.00

 

 

 

2

1.06

 .94

 

 

 

4

1.14

 .89

 

 

 

6

1.22

 .86

 

 

 

8

1.32

 .80

 

 

 

10

1.44

 .77

 

 

 

12

1.57

 .73

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT D   Allowable Lateral Lengths (Feet) for Three Pipe Diameters, Three Perforation Sizes, and Two Perforations Spacings 906.60 if system is to treat flow from more than 4 bedrooms)

 

Perforation Spacing (in)

Perforation Diameter (in)

(1 in)

(1¼ in)

(1½ in)

30

3/16

34

52

70

 

7/32

30

45

57

 

1/4

25

38

50

36

3/16

36

60

75

 

7/32

33

51

63

 

1/4

27

42

54

 

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT E   Dosing Quantity for Various Sized Homes

 

Home Size

No. Bedrooms

Gallons

Day

Dosing Quantity*

Gal/Dose

1

200

50

2

400

100

3

600

150

4

800

200

 

*      Each system must be checked to determine if this quantity is at least 10 times the lateral void volume.


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT F   Void Volume for Various Diameter Pipes

 

Diameter

inch

Volume

gal/ft/length

1

.041

.064

.092

2

.164

3

.368

4

.655

6

1.470

 

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT G   Pumping Chamber Sizes for Various Sized Homes

 

Home Size

No. Bedrooms

Minimum Pumping Chamber Size

Gallons

1

250-500

2

250-500

3

500-750

4

500-750


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT H   Perforation Discharge Rates in Gallons per Minute Versus Perforation Diameter and In-Line Pressure

 

In-Line Pressure

(ft)

Perforation Diameter (in)

 

 

 

 

 

 

 

 

1/4

5/16

3/8

7/16

1/2

9/16

5/8

1.0

0.74

1.15

1.66

2.26

2.95

3.73

4.60

1.5

0.90

1.41

2.03

2.76

3.61

4.57

5.64

2.0

1.17

1.82

2.62

3.57

4.66

5.90

7.28

3.0

1.28

1.99

2.87

3.91

5.10

6.46

7.97

3.5

1.38

2.15

3.10

4.22

5.51

6.98

8.61

4.0

1.47

2.30

3.31

4.51

5.89

7.46

9.21

4.5

1.56

2.44

3.52

4.79

6.25

7.91

9.77

5.0

1.65

2.57

3.71

5.04

6.59

8.34

10.29

 


Section 906.APPENDIX A   Illustrations and Exhibits

 

Section 906.EXHIBIT I  Friction Loss in Schedule 40 Plastic Pipe

 

FRICTION LOSS IN SCHEDULE 40 PLASTIC PIPE, C = 150

(ft/100 ft)

Pipe Diameter (in.)

 

Flow

1

2

3

4

6

8

10

gpm

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

1

0.07

 

 

 

 

 

 

 

 

2

0.28

0.07

 

 

 

 

 

 

 

3

0.60

0.16

0.07

 

 

 

 

 

 

4

1.01

0.25

0.12

 

 

 

 

 

 

5

1.52

0.39

0.18

 

 

 

 

 

 

6

2.14

0.55

0.25

0.07

 

 

 

 

 

7

2.89

0.76

0.36

0.10

 

 

 

 

 

8

3.63

0.97

0.46

0.14

 

 

 

 

 

9

4.57

1.21

0.58

0.17

 

 

 

 

 

10

5.50

1.46

0.70

0.21

 

 

 

 

 

11

 

1.77

0.84

0.25

 

 

 

 

 

12

 

2.09

1.01

0.30

 

 

 

 

 

13

 

2.42

1.17

0.35

 

 

 

 

 

14

 

2.74

1.33

0.39

 

 

 

 

 

15

 

3.06

1.45

0.44

0.07

 

 

 

 

16

 

3.49

1.65

0.50

0.08

 

 

 

 

17

 

3.93

1.86

0.56

0.09

 

 

 

 

18

 

4.37

2.07

0.62

0.10

 

 

 

 

19

 

4.81

2.28

0.68

0.11

 

 

 

 

20

 

5.23

2.46

0.74

0.12

 

 

 

 

25

 

 

3.75

1.10

0.16

 

 

 

 

30

 

 

5.22

1.54

0.23

 

 

 

 

35

 

 

 

2.05

0.30

0.07

 

 

 

40

 

 

 

2.62

0.39

0.09

 

 

 

45

 

 

 

3.27

0.48

0.12

 

 

 

50

 

 

 

3.98

0.58

0.16

 

 

 

60

 

 

 

 

0.81

0.21

 

 

 

70

 

 

 

 

1.08

0.28

 

 

 

80

 

 

 

 

1.38

0.37

 

 

 

90

 

 

 

 

1.73

0.46

 

 

 

100

 

 

 

 

2.09

0.55

0.07

 

 

150

 

 

 

 

 

1.17

0.16

 

 

200

 

 

 

 

 

 

0.28

0.07

 

250

 

 

 

 

 

 

0.41

0.11

 

300

 

 

 

 

 

 

0.58

0.16

 

350

 

 

 

 

 

 

0.78

0.20

0.07

400

 

 

 

 

 

 

0.99

0.26

0.09

450

 

 

 

 

 

 

1.22

0.32

0.11

500

 

 

 

 

 

 

 

0.38

0.14

600

 

 

 

 

 

 

 

0.54

0.18

700

 

 

 

 

 

 

 

0.72

0.24

800

 

 

 

 

 

 

 

 

0.32

900

 

 

 

 

 

 

 

 

0.38

1000

 

 

 

 

 

 

 

 

0.46