DOMESTIC SERVICES_PART 2_2019-2020.pdf

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 At the end of this topic, student should be able
CO1. Able to apply knowledge in construction to:
technology in the construction of building
and infrastructure. CO1 – PO1 1. Explain the aim and principles of external
(Engineering knowledge) drainage system;
CO2. Able to suggest appropriate construction 2. Explain each type of surface drainage
materials and techniques to suit various system;
construction requirements. CO2 – PO1
(Engineering knowledge) 3. Explain each type of subsurface drainage
system;
CO3. Able to evaluate construction problems
and provide technically viable solution. 4. Suggest a suitable solution for drainage
CO3 – PO2 (Problem analysis) problems.
 External (or exterior) drainage is a
removal of excess water to a
suitable outfall.
must be removed from all
areas such that water will Source of excess water:
not be retained in surface surface runoff,
depressions. subsurface & foul water

Maintain the hygienic and adequate Excess water is carried in the drains
disposal of foul water and to avoid to sewers, and from sewers to a
flooding and other damage. suitable outfall or treatment plant.

Benefit: erosion control,
Fig. 1. External Excess water
removal of surface water,
drainage is detrimental to the turf
and maintain soil’s
and other plant life and
structural capability and
need to be removed
improving trafficability.
Basic exterior sewers: subsurface,
surface, slope drainage, & downspout
& gutter system
 o water from a rainfall that does not infiltrate the
soil;
o excess rain or irrigation water will naturally flow
to areas of lower elevation.
o the excess water may remain ponded, causing poor
1. Surface Water aesthetic conditions as well as destroying turf or
damaging buildings, homes and hardscapes.
o surface water is considered to be clean and can
be discharged direct into an approved water
course or soakaway.

water contaminated by domestic
3
o
waste = effluent;
o require treatment to render it main forms of
clean before it can be discharged excess water in
into an approved water course. building drainage 2. Surface water
terms:

o results from surface infiltration;
o need to be collected from the earth to lower
the water table level in the subsoil;
3. Foul or Soil Water o considered to be clean and requires no
treatment and can be discharged direct into
the approved water course or soakaway.
 o the controlled removal of surface runoff
a) Channel drain resulting from precipitation and irrigation.
o it begins with shaping and smoothing the
b) Catch basins and inlets
land into a watershed that directs runoff to
o Install gutters and downspouts on 1. Surface drainage systems ditches, catch basins, storm sewers or other
homes to direct rainwater down and drainage systems.
away from the home, to reduce the o without proper surface drainage, subsurface
chances of saturating the soil around drainage efforts are considerably more
the foundation. difficult.

4. Downspout and gutter systems 2. Subsurface drainage systems
Roof drainage (gutter & 4 a) Deep open drains
rainwater pipe) basic types b) Pipe drain
residential c) French drain
drainage systems o the removal of gravitational water
o a slope drain is a pipe or lined channel from the soil.
which extends from the top to the o source of subsurface water is
bottom of a cut or fill slope. percolation (water moving vertically
o designed to convey concentrated and laterally underground) that is
runoff to protect exposed slopes from generally attributable to precipitation
upstream runoff.
3. Slope drainage systems or irrigation.
Slope drainage
 Comprehensive Drainage System

 Engineers and architects divide drainage into surface and subsurface drainages.
 A complete drainage system incorporates both surface and subsurface drains.
 Surface drains to remove heavy volumes of rainfall that fall in short spans of time and
subsurface drains to remove water which percolates into the soil.
 Soil has a natural ability to absorb just so much water.
 At the point the soil becomes 100% saturated with water, it cannot absorb anymore.
 With no place to go, additional rainfall accumulates on the surface resulting in flooding
and erosion.
 This is another reason it is critical to incorporate surface drains into any drainage plan.
 A. Drain Pipe Systems

1. 2. Sewer &
B. French Drain Corrugated Drain Pipe
Pipe

C. Half Round Drain

1. Perforated
Drainage components D. Rain Gutter 2. Solid

E. Channel Drain

F. Catch basins &
inlets Fig. 2. List of drainage
components commonly
G. Prefabricated drain installed in residential
system areas
 coils along the outer and/
A. Drain Pipe Systems or inner wall

1. Corrugated pipe

Two types of drain pipe
1. Perforated
systems for residential
2. Solid
drainage applications
smooth wall
2. Sewer & Drain
(S&D) (smooth
wall) pipe

Perforated pipe is used for subsurface drainage, and solid pipe is used to convey
water from surface and/or subsurface drainage systems.
 1. Corrugated pipe

Characteristics:
i. Manufactured from high density polyethylene vi. Corrugated pipe is available in solid or
(HDPE). perforated.
ii. Available from 10 ft. lengths to coils up to vii. The perforated version is sometimes known as
1,000 ft. long. slotted drain tubing.
iii. The longer the coil the fewer couplings viii. Perforated pipes are used for subsurface
necessary and the less labor required. drainage applications.
iv. Corrugated pipe is flexible & it can follow the ix. Coextruded dual wall corrugated pipe is a
contours of the ground, change directions in variation to single wall corrugated pipe.
the trench, and adapt to underground x. It is more rigid and has a smooth interior wall
obstacles more easily than rigid pipe. which gives it the characteristics of Sewer &
v. Labor savings and flexibility are two important Drain pipe.
advantages of corrugated pipe.
 1. Corrugated pipe

Disadvantages of corrugated pipe:
1. Plumber’s snakes cannot be used to clean out the pipe as they get caught in the pipe’s
corrugations.
2. Corrugated pipe and fittings snap together and, henceforth, are not watertight.
3. If slope is critical, the flexibility of corrugated pipe makes it difficult to obtain
constant slope unless the trench bed is sloped properly.
4. Corrugated pipe has more friction loss than smooth wall sewer and drain pipe, hence
reducing flow and increasing sediment deposits in the drain pipe.

Corrugated pipe and Corrugated pipe with Coextruded dual wall
Plumber’s snakes fittings perforation corrugated pipe
2. Smooth Wall Sewer & Drain Pipe (S&D)
S&D pipe is much more rigid than corrugated pipe and
manufactured from PVC, ABS and Polyethylene.

Easy to maintain a continuous slope in critical areas.

Will compensate for peaks and valleys in the trench bed.

PVC and ABS connections can be solvent welded or glued
together ensuring watertight connections.

Drain snakes can be used on S&D pipe if the pipe line
becomes clogged.
2. Smooth Wall Sewer & Drain Pipe (S&D)
However, S&D pipe is more labor intensive and less
flexible than corrugated pipe.

S&D pipe is available as ASTM 2729, ASTM F810 or SDR
35.

SDR 35 has a thicker wall and stronger crush strength
than ASTM 2729 or smooth wall polyethylene pipe.

SDR 35 pipe is more expensive than ASTM 2729 or
polyethylene pipe.

Another type of S&D pipes are: DWV (Drain Waste &
Vent) - used in indoor sewer application.; and PVC schedule
40 - used in pressure application such as lawn sprinkler
systems.
 B. French Drain

▪ French drains (Fig. 3) are a type of subsurface
drain, utilize a buried perforated pipe installed
in a gravel bed with a filter sock or geotextile
fabric envelope lining the trench.

▪ Water from the surrounding soil enters the
gravel bed, flows into the drain pipe and utilizes
gravity to flow towards the discharge point.

▪ Perforations in single wall corrugated pipe are
slits surrounding all sides of the pipe.

▪ Perforations in smooth wall drain pipe (S&D) and
coextruded dual wall corrugated pipe are small
diameter holes located in rows on one side of
the pipe which should always face downward to Fig. 3 French Drain
prevent soil from infiltrating the pipe.
 B. French Drain

▪ French drains are the most common method for
evacuating excess ground water which has
infiltrated into the soil.

▪ However, French drains require labor, large
trenches, rock or stone, filter fabric and
therefore are more expensive than surface
drainage systems.

▪ Migrating soil fines will accumulate on the filter
fabric or in the drain pipe, potentially inhibiting
water flow and eventually clogging, limiting the
life of the drain system (Fig. 4). Fig. 4 French Drain pipe
 C. Half Round Drain

▪ Half Round Drain - Common type of drain ▪ Perfect for both domestic and light commercial
used in Malaysia’s residential for rainwater applications,
drainage.
▪ The half round rainwater system comes in 75
mm, 112 mm and 150 mm diameter if more
capacity is required.

▪ Available in grey, black, brown and white to suit
most environments;

▪ Light weight makes high work safer;

▪ Quick and easy to cut and join;

▪ No painting and minimal maintenance required.
Fig. 5. Half Round Drain
 D. Rain Gutter

▪ A rain gutter or surface water collection
channel is a component of water discharge
system for a building’s roof (Fig. 6).
▪ Gutters prevent water ingress into the fabric
of the building by channeling the rainwater
away from the exterior of the walls and their
foundations.
▪ Many materials have been used to make
guttering: cast iron, asbestos cement, UPVC
(PVCu), cast and extruded aluminium, wood,
copper, and bamboo.

Fig. 6. Rain gutter
 E. Channel Drain

▪ A.k.a. as trench drain, linear drain, line drain, slot
drain, or strip drain.
▪ It is linear surface drains connected together to a
length appropriate for the specific installation (Fig.
7).
▪ Runoff water collected in the drain is discharged to
bottom or end outlets, or catch basins all of which
are connected to drain pipe. o available in
▪ Act as perimeter drain at the edge of the slope. different materials:
concrete, steel,
▪ Ideal applications for channel drains are hardscapes plastic.
or large flat work areas of concrete, asphalt, brick, o grates are available
pavers, etc. in cast iron, steel,
brass and plastic
▪ [hardscape generate more runoff than landscapes
due to lack of water absorption].
Fig. 7. Channel Drain
 F. Catch basins and inlets

▪ Catch basins and inlets used in conjunction with a
drain pipe system – to remove large amounts of
surface water from an affected area.
▪ Typically used in low areas of turf landscapes,
hardscapes, driveways, parking lots, etc.
▪ Catch basins and inlets are traditionally available in
sizes from 3” round to 48” square and different
materials including concrete, brick, and plastic
basins, cast iron, steel, brass and plastic grates.
▪ A catch basin should be used in areas where debris Fig. 8. Catch basin
like mulch, leaves, sand, silt or grass clippings are & inlet
prevalent
 G. Prefabricated drain system

▪ Prefabricated drain systems are typically
rectangular with a narrow profile and
available in 4” through 60” depths.
▪ They are a type of subsurface drain and
used in both natural and synthetic turf
applications to collect and convey water
away from the problem areas.
▪ Compared to French drains, their narrow
cross-section allows them to be installed in
more narrow trenches without significantly
disrupting natural turf areas (Fig. 9).

Fig. 9. Prefabricated drain system
 G. Prefabricated drain system

▪ A prefabricated drain system usually consists of a
cuspated plastic core which is completely wrapped in a
geotextile fabric. GEOTEXTILE FABRIC

▪ The fabric may be glued to the core or sewn.
▪ The geotextile prevents intrusion of fine soils into the
drainage core.
▪ Water passes through the fabric and flows through the
core to the discharge point.
▪ The geotextile filters the fine-grained soil particles
leading to the development of a stable filter cake.
Fig. 10. The component in
prefabricated drain
 Others types of drains

Swales:
▪ Natural surface drain swales are the least expensive method of Swales
removing undesired surface water run off. The fabric may be
glued to the core or sewn.

Terraces :
▪ The primary purpose of terracing is to move surface runoff water
from sloping areas. Bench terraces and tile outlet terraces are
the two types of terraces that have been used in turf drainage. Terraces
Water passes through the fabric and flows through the core to
the discharge point.

Culverts:
▪ Culverts can be installed under flat work, gravel or dirt to allow
water to pass under an obstruction.
Culverts
 A. Good Design Practice

B. Basic Components

Surface Drainage System C. Roof Drainage System

D. Channel Drain

E. Catch Basins & Inlets Fig. 11. The Outline
 A. Good Surface Drainage Design Practice

▪ A drainage system has 3 major phases: ▪ This capacity can be calculated using the
collection (catchment), conduction, and dispose following formula:
(discharge) of drainage water.
Annual rainfall (in mm) x Roof surface area (in m2)
▪ The design process is simply a continuation of: = Roof catchment capacity.
1. what size the catchment (collection)
system needs to be, ▪ Conducting system (gutters) - channels all
2. what size and type the conducting system around the edge of a sloping roof to collect and
needs to be, transport rainwater to the downspout.
3. what format the disposal/discharge system
should take. ▪ Disposal/discharge system – 2 widely used
components for disposal are Flo-Well and Pop-
▪ Catchment system – collection of rainwater. Up emitter.

▪ Roughly speaking, 1 mm of rain over a m2 of roof ▪ Rainwater or surface water should not be
= 1 L of water. discharged to a septic tank/ waste water
treatment system.
 A. Good Surface Drainage Design Practice

▪ A surface water drainage system should:
1. carry the flow of rainwater from the roof
to an outfall,
2. minimize the risk of blockage or leakage,
3. be accessible for clearing blockages,
4. be adequately protected from accidental
damage from sources such as traffic,
ground settlement and tree roots,
5. be adequately protected from accidental
Fig. 12. Components for pollution by means of a discharge from foul
disposal: Flo-Well and Pop-Up drains, oil spillage or other pollution
emitter sources.
 B. Basic Components

▪ Poor drainage causes obvious problems: standing GUTTER
water, foul odor, diseased or dying plants, mud,
ruined turf, and basement water.

▪ Surface drainage system should transfer the
runoff water (rainwater) from roofs, paved
areas and other surfaces of a premise to a
suitable outlet or disposal facilities.

▪ The system involves: gutter, downpipes (down
spout), drains, pipes, swales, storage and
treatment facilities (if necessary).

▪ Typical surface drainage components for
residential in Fig. 13:

Fig. 13. Typical surface drainage components
 C. Roof Drainage System (gutter & downspout)

▪ A roof drainage system is a system that is ▪ The water will then flow through the gutter and
installed on the roof to divert water and debris then make its way to the downspout where it
off the roof. will then absorb into the ground.

▪ The components for a roof drainage system are ▪ A gutter not only help collect water from the
a gutter system and downspouts (Fig. 14). roof, but it will also protect the landscaping
from soil erosion and home’s foundation from
▪ A gutter system is a component of a roof cracking.
drainage system, which allows water, twigs,
leaves, and other debris to collect off of the gutter
roof and flow toward the downspout and onto
the ground.

▪ The water from the roof drips into the gutter
system, which is a long piece of material that is
installed along the edge of the roofline. downspout

Fig. 14. Gutter and downspout
 C. Roof drainage system eaves gutter
(gutter & downspout)

▪ 3 types of gutters (Fig. 15): eaves gutter, box
gutter and valley gutter.

▪ Eaves gutters are located on the outside of a
building.

▪ Box gutters and valley gutters are located box gutter
within the plan area of the building and the
intersecting sloping surfaces of a roof,
respectively.

▪ The traditional material for domestic gutters
and rainwater pipes is cast iron but uPVC
systems are very often specified today because
valley gutter
of their simple installation and low maintenance
costs.

Fig. 15. Types of gutters
A closed eave has very Open eaves is an
little or no overhang overhanging eaves where
(extension beyond the the rafters and
siding). underside of the roof
are visible from below.

Fig. 16. Eaves Gutter Types
 C. Roof drainage (gutter & rainwater pipe) installation

▪ Installing a roof drainage system is depending ▪ The flow into a gutter depends on the area of
on types of roof (either flat or pitched roof) surface being drained and whether the surface
and the size of the roof. is flat or pitched. (Tab. 16)

▪ For a flat roof, the drain will be installed onto
the actual roof and then the drain will be linked
together.

▪ For pitched roofs, the water will just flow into
the gutter system.

Fig. 17. Typical eaves details
 C. Roof drainage (gutter & rainwater pipe) installation

▪ Table 17 shows the largest effective areas ▪ The Table shows the smallest size of outlet
which should be drained into the gutter sizes which should be used with the gutter.
which are most often used.

▪ These sizes are for a gutter which is laid level,
half round in section with a sharp edged outlet
at only one end and where the distance from a
stop end to the outlet is not more than 50 times
the water depth.

▪ At greater distances, the capacity of the
gutter should be reduced.

▪ Gutters should be laid with any fall towards the
nearest outlet.

▪ BS 6367: 1983 Code of practice for drainage of
roofs and paved areas.
C. Roof drainage (gutter & rainwater pipe) installation

Rainwater pipes should discharge
into a drain or gully but may
discharge to another gutter or onto
another surface if it is drained.

gully trap
Fig. 18. Rainwater pipe connection
to gully
C. Roof drainage (gutter & rainwater pipe) installation

Rainwater pipe which discharges
into a combined system: sewers that
carry foul wastewater and surface
water in the same pipe, should do so
through an intercepting trap.

intercepting
traps
Fig. 19. Rainwater pipe
discharged into a combined
system
 C. Roof drainage (gutter & rainwater pipe) installation

▪ The size of a rainwater pipe should be at least ▪ Different metals should be separated by
the size of the outlet from the gutter. nonmetallic material to prevent electrolytic
▪ A down pipe which serves more than one gutter corrosion.
should have an area at least as large as the
combined areas of the outlets.
▪ The materials for gutters, rainwater pipes and
joints used should be of adequate strength and
durability.
▪ All gutter joints should remain watertight under
working conditions.
▪ Pipes inside a building should be capable of
withstanding the airtightness test.
▪ Gutters and rainwater pipes should be firmly
supported without restricting thermal
movement, and Video 1. How to install gutters & downspout
 D. Channel drain installation

▪ Channel drains are a variation of surface drains, Standard installation
ideal in hardscapes such as patios, walkways,
swimming pools, parking lots and driveways.
▪ The hardscape surface is slightly sloped in one
direction or plane to the perimeter channel
drain with the same principle as a gutter on the
roof of a building.

Fig. 20. Channel Drain Video 2. Channel Drain Installation
 D. Channel drain installation

Standard installation

1. Excavate a wide and deep trench to 5. Design bottom or end outlets into the channel
accommodate the channel and bedding concrete run in the appropriate location and glue to the
or sand. drain pipe or fittings.

2. Erect a string line at each end of the drain run 6. PVC cement end caps where appropriate.
as a guide for laying the channels to the
required level. 7. Using either wood, plastic or steel stakes, 1/2”
or 5/8” rebar, anchor channel to the trench
3. Begin channel installation at the discharge end bed every 24” on each side of channel.
of the run where the outlet(s) are located.
8. Backfill with either concrete, sand, or soil
4. Install channel end-to-end PVC cementing depending on the application.
sections together.
9. Pour slab to grade and finish concrete.
 Channel drain installation

▪ Figure 21 illustrates a non-vehicular traffic ▪ Figure 22 illustrates a concrete base
installation in which a concrete base is not underneath the channel recommended for light
required. Compact soil and a 1” sand base. traffic and heavy load applications.

Fig. 21. Channel drain for non-vehicular traffic Fig. 22. Channel drain for heavy load application
 Catch basins and inlets installation

▪ Catch basin – A structure with a grate on top used 3. An inlet is often installed directly on top of the
to collect and divert surface runoff to an drain line (Fig. 23). Use catch basins in
underground drain pipe system. At the base of the applications where it is necessary to collect
catch basin is a sump or sediment trap to collect debris from runoff water in a sump area. This
debris. helps minimize clogging of drainage pipes.
▪ Inlet – A grate on top of a pipe riser that allows
water runoff to enter directly into a drain pipe and
does not contain a sump.
Installation
1. Choose an inlet or basin size according to the
amount of rainfall, surface area and soil type. It
may be necessary to install more than one inlet
or basin to accommodate excessive runoff or a
combination of low spots.
2. Locate low spot or any area where excess water
will accumulate. Fig. 23. Catch basin & inlet
 Catch basins and inlets installation

4. Dig a hole deep enough for overall height of 10. Ideally, the catch basin outlet should be
basin and grate. equipped with an elbow facing down to prevent
debris from washing into the outlet drain line
5. Install basin in hole on top of a firm base. (Figure 7-3).
6. Work from the discharge point back to the
grate. 11. For hardscape installations, the grate should
be installed and taped over prior to pouring
7. Excavate the base of the trench with a minimum concrete or backfill to prevent debris from
1% to 2% slope to ensure drain pipe slopes to the entering drain.
discharge point.
12. The tape is removed immediately after
8. Connect pipe to the basin. Backfill trench and
area around basin. installation. In landscape installations, straw
bales or fabric can be used to protect the
9. Ideally, the catch basin incoming drain line grate during construction.
should be at an elevation equal to or higher than
the outlet drain line.
 Catch basins and inlets installation

Installation (cont’d)

13. Grates should be recessed below grade a 17. Basins should be installed on top of compacted
minimum of 1/8” for non-traffic installations gravel, sand or concrete.
and 1/4” for traffic installations.
18. To avoid standing water in the basin, drill
14. Basin or inlets may be encased in concrete for holes in the basin bottom. This will allow
heavier load applications. excess water to leach out. A gravel base is
recommended for this application.
15. In asphalt or hot mastic applications the basin
should be encased in concrete for strength 19. Finish grade should slope a minimum 1% to 2%
and to prevent distortion. to the grate.

16. PVC primer and medium body fast set PVC
solvent cement should be used to cement all
components. Tape should be used to connect
corrugated pipe to components.
Catch basins and inlets installation

Video 3. Catch basin & inlet
Installation
 A. Drain Types

B. French Drain

Subsurface Drainage
System

C. Prefabricated Drain
system

Fig. 24. The Outlined

D. Flo-Well and Pop-Up
Emitter
 A. Drain Types

▪ Subsoil drainage systems are provided to
drain away subsurface water in order to:
1. increase the stability of the ground and 4. increase soil strength by reducing the
footings of buildings by inducing a more moisture content.
stable moisture regime and reducing
▪ Classification of subsoil drain systems:
foundation movements due to the
variations in the soil moisture content; 1. French drain;
2. mitigate surface water ponding and 2. Prefabricated drain;
waterlogging of soils by lowering water
tables; 3. Flo-Well & pop-up emitter.

3. alleviate ground water pressures likely
to cause dampness in below-ground
internal parts of buildings or damage to
foundations of buildings, other
structures, or pavements; and/or
 A. Drain Types

The types of subsoil drains commonly used:

Fig. 25. Types of
Subsurface Drain
 A. Drain Types
▪ Subsoil drains may be installed on flat ground, in a sag or depression, or
on sloping ground.
(a) Basic system:
a trench with fill or
filter material
(commonly sand or
gravel). A.k.a. rubble
drain.

(b) Geotextile filter: (c) Pipe drain:
the addition of a the addition of a pipe to promote more
geotextile lining to rapid drainage. A.k.a. French drain. This
prevent external fine is the most common type of subsoil drain.
soil particles being The pipe is perforated to allow easy
washed into the filter entry of water and can be rigid or
material and clogging flexible.
it.
 A. Drain Types

(d) Pipe Drain with Capping to Exclude Surface (e) Geotextile Around Pipe:
Water:
two further variations – an impervious cap for The pipe is wrapped in geotextile to
situations where the drain is intended to prevent piping and loss of filter
collect only subsurface flows, and bedding material.
material for cases where the base of the
excavation is unsuitable as a pipe support.
 A. Drain Types

filter
material
(soil)

geotextile

(f) Geocomposite (g) Geocomposite
Drain in Narrow Drain in Shallow (h) Soil Filter Layer to Avoid
Trench Trench Clogging of Geotextile:
Geocomposite drains of various an external layer of filter material
configurations and manufacture can be provided around the geotextile
provided. These are usually of plastic encompassing the filter material.
wrapped in geotextile and various This might be used where there is
proprietary systems are available. a likelihood of fine particles or
deposits, e.g. iron precipitates,
clogging the geotextile.
 B. French Drain Installation

▪ The most reliable way to eliminate undesirable, ▪ Slotted pipes are better than pipes with small
free-standing water is to install French drains round holes because they tend to reduce the
with slotted pipes, filter fabric and gravel. amount of fine soil particles that get into the
pipe.
▪ The old way of installing French drains is to do
it without the gravel and the fabric.

▪ Without the gravel and the fabric, however, the
drain can clog up with sand and soil over time.

▪ The best practice for installing French drains is
to use perforated drainage pipes, which allow
water to enter or exit through small openings
along the pipe.

▪ The perforations (openings) can be circles or
slots. Fig. 26. French Drain
Installation
 B. French Drain Installation

1. Dig a trench along the outside of your footing. 2. Lay the pipe on the virgin soil. It is very
The trench should be at least 2 feet wide, and important that the pipe always be sloped from a
can be as deep as 6 feet for a basement or as higher starting point to an ending point of lower
shallow as 2 feet for a slab-on-grade home. elevation, so gravity can force the water out.

3. The grade should always slope away from the
home to ensure that the water is directed away
from the walls of the home.

4. Cover the pipe with at least 12 inches of washed
gravel.

5. Lay filter fabric over the gravel to prevent any
soil from clogging the pipe.

6. Back-fill the foundation with top soil back to its
Fig. 27. The Trench
original grade height.
 B. French Drain Installation

Video 4. French Drain using Video 5. French Drain using
Corrugated Pipe Perforated S&D Pipe
 C. Prefabricated Drain Installation

o Prefabricated Drain Systems (Fig. 28), are an
alternative to French drains.

o Sometimes called vertical or strip drains.

o Ideal for heavy use areas such as athletic fields
and golf courses.

o Limited usage in residential area.

o For subsurface drainage, the drain should not
be covered with soil. Instead, cover it with sand
to the surface.
Fig. 28. Prefabricated
o Proper installation will prevent unhealthy turf Drain
directly above the subsurface drain lines.
 C. Prefabricated Drain Installation

1. The sod is cut and removed from the trench. 5. Excavated soil should not be used as backfill
unless it has minimal silt or fines. The use of
2. Drainage trenches should be deep enough to excavated soil for backfill prevents drainage of
allow appropriate soil cover over the drain to the surface and sod. See backfill specifications
establish healthy turf and a minimum 2” space below.
below aerifier lines. The drain should be at a
depth to collect the ground water desired. 6. The temporary wood stakes are removed.

3. The drain is placed in the trench and may be 7. The sand is flooded with water, not tamped, to
centered using temporary wood stakes. On promote proper compaction.
hillsides, the drain is placed on the uphill side of
the trench. 8. For surface water installations, the trench is
topped off with sand to bring the backfill up to
4. The trench is backfilled with select sand the top of the trench, allowing for sod.
backfill. If soil from the trench is a porous Subsurface installations can be topped off with
granular media, the trench may be backfilled soil and sod.
with soil excavated from the trench.
9. The sod is then placed back over the trench.
 D. Flo-Well and Pop-Up Emitter

o Consists of 2 units: (1) Flo-Well unit; and (2)
Pop-up emitter.

o Both are used as discharged points.

o Flo-Well is a dry well, collect, retain, and direct
storm water on-site.

o Pop-up Emitters acts as the discharge point of
a drainage system, allow water captured
through drainage system to be released in
water-safe locations like curbside drains.

o The pop-up emitter is opened by the
hydrostatic pressure of water flowing through
the drain pipe and as flow diminishes the
emitter closes. Fig. 29. Flo Well
Installation
 D. Flo-Well and Pop-Up Emitter

o Pop-up Emitters have a flat profile and are
spring-loaded to automatically close during dry
weather, preventing damage from lawnmowers
and keeping pests out of the drainage system.

Fig. 30. Pop-up Emitter
D. Flo-Well and Pop-Up Emitter

Video 6. Flo-Well and Pop-Up
Emitter Installation
▪ Soakaways are used to manage surface water at
its source, and serve as an alternative option to
draining off (dispose) surface water via a
stream or sewer system.

▪ A soakaway is a hole dug into the ground, filled
with rubble and coarse stone which allows Fig. 31. A 3D Illustration of
surface water to percolate back into the earth Soakaway
close to where it falls.

▪ As part of a full drainage system it is an
efficient and low environmental-impact way of
dealing with surface water (also called runoff,
rain water or storm water).

▪ There will be a pipe leading into the soakaway,
from the area where there is excess water, like
a gutter from a roof, a driveway drain or a
French drain.
Fig. 32. A Soakaway
Installation
▪ Soakaways are probably the most common form ▪ A soakaway must always be the first choice but
of surface water disposal and are usually must not be used:
suitable for areas less than 100m².
1. Within 5m of a building or road, 2.5m of a
▪ Soakaways are generally formed from square or boundary or in an area of unstable land in
circular pits, filled with rubble or lined with dry ground where the water table reaches the
jointed masonry or perforated concrete ring bottom of the soakaway at any time of the
units. year.

▪ For soakaways serving areas greater than 25m² 2. Near any drainage field, drainage mound or
reference should be made to BS EN 752-4, or other soakaway so that the overall soakage
BRE Digest 365 Soakaway design. BRE Digest capacity of the ground is exceeded and the
365 is the most commonly used document. effectiveness of any drainage field
impaired;
▪ Percolation tests should be carried out to
determine the capacity of the soil. 3. Where the presence of any contamination
in the runoff could result in pollution of
groundwater source or resource.
▪ Soakaways must be at least 5 meters from any habitable building.

Fig. 32. Cross section of a Drainage System
Including a French Drain and Soakaway