Unit 3 - Drainage.pptx

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Unit 3: Drainage
 INTRODUCTI
ON

 Civil engineer – Roads (Surface water) or underground
pipes (water mains, foul sewer and stormwater.
 Housing contractor – internal and external pipes for
potable water into a house and wastewater out.
 Geotechnical engineer – sub-surface water and the effect on
soil conditions (water table)
 INTRODUCTI
ON

Different forms of drainage:
 Surface water
 Sub-surface
 Natural and
 Man-made
 INTRODUCTI
ON

 Arrangement of drainage scheme governed by:

 Internal layout of connection
 External pipe position
 One building to another
 Location of public pipes (sewer and stormwater) and
water connections
 Topography
Definitio
n
Definitio
n
 Drainage
materials

Drainpipes :
Rigid : Clay (Domestic) and Cast iron
Flexible: Pitch fibre and unplasterised
PVC
 Drainage materials –
Vitrified clayClay
pipes (VC)pipes
: Not in use mainly due to their brittleness.
Specification:
 SANS 559: VC sewer pipe and fittings – Specifies all pipe covers,
fittings, and their physical properties including dimensional
tolerance, and soundness. It also sets the requirements for crushing
strength, water absorption, sampling, and testing.
 SANS 974: Rubber joint rings (no-cellular)- defines the type of
rubber and its specifications to be used in the manufacturing of joint
rings e.g. hardness, tensile strength, and acid resistance.
Code of practice
 SANS 058: The installation of sewerage and drainage
nonpressure pipelines.
 SANS 1200 series: Standardised specification for civil
 Drainage materials –
Clay pipes
Specifying clay pipes:
Points to consider
 Comply with SANS
559
 Sewerage and
drainage must be
specified with flexible
mechanical joints
 Rubber rings comply
SANS 974
 Always refer to code
of practice
 Drainage materials –
Clay pipes
Clay pipes – Joints
Caulking material discontinued because:
 The joint was so rigid and stiff that it did not allow for ground
movement.
 Bacterial in the sewerage attack cement-based mortars causing
expansion and subsequent cracking
The caulking operation required skilled pipe-layers
 Drainage materials –
Clay pipes
Clay pipes – Joints
Caulked joints replaced by mechanically flexible
joints,
Four types are currently used:
 Rolling rubber ring,
 Elastomer spigot and socket,
 Sleeve and spigot, and
 Plain-ended pipes with jointing sleeve and gasket.
 Drainage –

Drains
Drainage requirements according to local authority regulations must be
adhered to.
Some drainage systems are designed to ensure that the gradient for
pipes is laid to a maximum of 1:6 and minimum of 1:60.
Minimum cover of 800mm, or encased by 150mm concrete if pipe
has to be shallower.
Accessible for cleaning and inspections
Flexibility to avoid cracking, jointing is used for all drains.
Anchor blocks normally made of mass concrete are used to prevent
pipes from moving and are usually placed at bends or where the
slope of the pipe is greater than 1 in 60.
Sewerage pipe’s minimum gradient is determined by the minimum
permissible full bore velocity which under normal circumstances
must not be less than 0.9m/s.
 Drainage –
Drains
Manholes – The distance between manholes depends on
the size of the sewer and the type of cleaning equipment
utilised.
General location:
 Changes in direction and gradient,
 Junctions,
 Head of each sewer, and
 Intervals not exceeding 100m for straight runs.
 Drainage –
Manholes constructed:
Drains
 To permit minimum groundwater infiltration as this will contribute to
the flow
 Normally constructed of bricks (1200x800mm) or 1250mm precast
concrete rings.
Manhole shaft from 600x600 brickwork or 750mm precast
concrete.
 Steel step-irons are provided inside the manhole for access.
The floor of the manhole consists of a half-round vitrified clay pipe that is
secure in concrete benching. If connection at different levels is required
then a backdrop system is used consisting of two bends and a length
of pipe between them
 Drainage –
Drains
Installing pipes, factors to consider:
 Always try to schedule pipe laying and back filling to follow as soon as
possible after excavation.
 Ensure correct earth cover when back filling as overloading may occur.
 Adhere to trench widths as specified on drawings, as this determines
the loading on pipes.
 Ensure correct pipe bedding.
 Shoring of excavated sides may be necessary for deep trenches.
 Keep the excavated soil away from the sides of trenches to avoid
possible collapse.
 Ensure the correct alignment/grades of pipe when installing.
 Use granular material to level out the trench floor.
 Handle pipes carefully to prevent the breakage of pipes and jointing.
 Drainage –
Drains

Correct alignment/grades
of pipe
 Drainage –
Drains
Bedding and back filling of pipes is fundamentally
important to their performance.
 The type and class of bedding are usually specified in
the contact documents or on drawings.
 No hard or soft spots on the trench floor, as pipes
need to lie on a firm bas
Four types of bedding used in SA:
 Class A bedding
 Class B bedding Self study

 Class C bedding
 Class D bedding
 Drainage –
Drains
Back filling
 Due to the brittle nature of all pipes, initial back filling
should be of selected material, for example sand, placed
in layers of approximately 100 mm and compacted by
hand for the full width of the trench.
 The main filling can be placed and mechanically
compacted once the initial back fill has reached a level
approximately 300 mm above the pipe.
 Drainage – Clay
Pipes
Advantages –Clay pipes Disadvantage –Clay pipes
 Inexpensive Brittle
 Strong in compression Tendency to shear at
 Resistant to sewer gas, erosion manholes
and
corrosion High impact loading
 Flexible joints Controlled back filling
 Easy to handle conditions to prevent
damage
 Drainage –
Other types of pipes
 Cast iron
 Only considered for domestic drainage in
special circumstances such as sites with
unstable ground, drains with shallow inverts
and drains that pass under buildings.
 Cast iron are made with a spitgot and
socket for rigid or flexible joints.
 A protective coating is applied using a hot
tar composition or a combination of coal
solution and bitumen composition.
 This coating gives the pipes good protection
against corrosion and reasonable durability
in average ground conditions
 Drainage –
Other types of pipes
 Pitch fibre pipes
 Suitable for all forms of domestic drainage
and because of smooth bore, with its high
flow capacity, they can generally be laid to
lower gradients than most other materials.
 Pitch fibre pipes and fittings are made from
pre-formed felted wood cellulose fibres that
have been thoroughly impregnated under
vacuum pressure with atleast 65% (by
weight) cold tar pitch or bituminous
compounds.
 Diameters range from 50 to 225 mm with
general length of between 2400 and
3000m,
 Drainage –
Other types of pipes
 uPVC pipes
 These pipes and fittings are made from
polyvinyl chloride and additives needed to
manufacture the polymer and produce a
sound, durable pipe.
 They are obtainable with socket joints for
either a solvent welded joint or a ring
sealed joint.
 Like pitch fibre pipes, PVC pipes have a
smooth bore, are light and easy to handle,
come in long lengths ( reducing the number
of joints required) and they can be jointed
and laid in all weathers.
 Drainage –
Concrete pipes
 Concrete pipes – Non pressure pipes and Pressure pipes

 Non-pressure pipes are used for low or non-pressure applications (e.g.
storm water or sewerage) and are manufactured in different sizes and
classes.
 Pipe design is influenced by the depth and width of the trench, back fill
material and loading.
 Non-pressure pipes are classified according to their proof load and
ultimate load.

Proof load can be defined as the load that a pipe can sustain without
significant cracking. Cracking should not exceed 0.25 mm in width over a
length of 300 mm or more when tested.

Ultimate load refers to the maximum vertical load the pipe will support
when tested.
 Drainage –
Concrete pipes
Pressure pipes are used in pipelines that carry
liquids under pressure (e.g. water mains). They are
manufactured in different sizes and classed according
to pressure. The class of a pressure pipe is defined as
the factory test pressure that the pipe can sustain for
two minutes without leakage.
Drainage – Pipe
loads
Drainage – Pipe
Jointing
 Methods of
jointing
Some of the rules to be followed when joining pipes
 Ensure that the surfaces of the joint and the rubber ring are clean.
 Align the pipes correctly before jointing.
 Lubricate the rubber ring and grease the socket before placing in the
groove.
 The spigot end of the pipe to be laid should be drawn up so that it just
enters the socket of the previously laid pipe.
 For pipes smaller than 600 mm (on a non-granular bedding) use a wooden
block behind the socket end of the pipe and a vertical bar as a lever to
move the pipe into position.
 Use a sling at the centre of gravity for heavier pipes to align the pipe.
 Thereafter use a pulling device or turfor to pull the pipe into position.
 Pipes with socket joints are laid against the flow – they start at the lower
end and work towards the upper end.
 Surface drainage
(rainwater)
 Semi-circle or box-shaped gutters are fitted to
buildings to collect rainwater that falls on the roof
and conducts the flow into downpipes.
 The rainwater pipe is terminated at its lowest point
by a rainwater shoe for discharge into a surface
water drain or a trap gulley. From here, the flow is
directed into further channels on the property or
into the formal stormwater drainage system
usually located in the road.
 The pipes used for domestic rainwater installations
are made of asbestos or unplasticised polyvinyl
chloride (uPVC).
 Surface drainage
(rainwater)
The advantages of uPVC include:
 easier jointing
 no gutter bolts are required
 the joint is self-sealing (the pipe has a built-in
rubber seal at the joint)
 there is no corrosion
 decoration (painting) is usually not required as the
pipe is often used underground
 breakages are reduced
 better flow properties enable smaller sections and
 Pipe and gutter
sizing
The size of the gutters and downpipes to
effectively cater for the discharge from a roof
will depend on:
 the area of roof to be drained
 the anticipated intensity of rainfall
 the material used for the gutters and
downpipes;
 the fall within the gutter
 the number, size and position of outlooks.
Pipe and gutter
sizing
 Pipe Testing
Water test. This involves filling the drain with water
under pressure and observing if any water escapes.
Smoke test. Smoke is pumped into the pipes and the
float on the smoke machine is checked for any fall in
pressure.
Air tests. This is not a particularly conclusive test, but it
is sometimes used in special circumstances, such as
large diameter pipes, where a large quantity of water
may be required. If failure is indicated by an air test, the
drain should be re-tested using the more reliable water
test. In South Africa, the water test is the test most often
applied on construction sites.
 Public vs Private
sewer

Public sewer is owned and maintained by the local
authority; and
Private sewer is owned by single or group of people and
maintained by them.
 Savings in connecting to private sewer
then into
public sewer
 A number of houses can be connected to a single
(private) sewer that, in turn, is connected to a public
sewer.
 Depending on the number of houses connected to the
private sewer and the distance from the public sewer, the
savings are possible in the following areas
Total length of drainpipes required;
The number of connection to the public
sewer;
The number of openings in the road; and
The number of inspection chambers.
 Connecting to private sewer into
public sewer

The method of connection will depend on
several factors:
the relative sizes of the sewer and the connecting
drain or private sewer
relative invert levels
the position of nearest inspection chamber on the
sewer run
whether the sewer is existing or being laid
concurrently with the drains or private sewers
the type of joints or junctions built into the
existing sewer
 Design factors of soak-
aways
A soak-away is a pit dug in permeable ground that receives
rain water or sewerage water. It is constructed in such a way
that the water can percolate into the surrounding subsoil..
To function correctly and efficiently, a soak-away must be
designed taking into account the following factors:
The permeability or rate of dispersion of sub-soil;
The area to be drained;
The storage capacity of the soak-away needed to accept a
sudden inflow of water;
The local authority requirements regarding method of
construction and siting in relation to buildings; and
The depth of the water table.
 Design factors of soak-
aways

The rate at which water percolates into the ground
depends on the type of soil where it collects.
Generally, clay soils are unacceptable for soak- away
construction, whereas sand and gravel are usually
 Principles of good
drainage
 The materials used for the pipes should have adequate strength and durability.
 The diameter of the drainpipe should be as small as is practicable. Pipes that
are put in soil should have a minimum diameter of approximately 100 mm. For
surface water pipes – for example, gutters – the minimum diameter is 75 mm.
 Every part of a drain should be accessible for inspection and cleaning.
 Drainpipes should be laid in straight runs are far as possible. For obvious
reasons, the more curves, corners or joints in the pipe, the more difficult it will
be to clean.
 Drains must be laid to a gradient that will render them self-cleansing. The fall
or gradient should be calculated according to the rate of flow, velocity required
and the diameter of the drain.
 Inspection chambers or manholes should be placed at points of change. The
direction size of pipe, junctions and the gradient may hinder a drain from being
readily cleanse
 Principles of good
drainage
 Inspection chambers or manholes must also be placed within 12.5 m of a drain
junction. The maximum distance allowed between manholes is 90 m.
 Drain junctions must be arranged so that the incoming drain joins at an oblique
angle in the direction of the main flow.
 Try to avoid laying drains under buildings. If this is unavoidable, they must be
protected to ensure water tightness and to prevent damage to the building or to
the pipes. Standard protection methods include: - encasing the drain with 150
mm minimum of mass concrete; and - using cast iron pipes under the building.
 Drains that are within 1.0 m of the foundations for the walls of buildings and
below the foundation level must be backfilled with concrete up to the level of
the underside of the foundations.
 Where possible, the top of the drain should be a minimum of 450 mm below
the ground surface to avoid possible damage from ground movement and
traffic.
 Sub-surface drainag
 Subsoil drains are pipes that are placed
below the soil surface to control the
water level.
 Different applications - mainly for roads
and agriculture.
 There are several ways of constructing
subsoil drains using precise
specifications, but generally they
consist of a piping system, a geotextile
fabric acting as a filter for the fine
material and coarse aggregate.
 Water can reach a road foundation by
infiltration from the surface, through
natural seepage from the high side of
the road, or through capillary rise from
 Sub-surface drainag

Interceptor drains are situated on the high side
of and parallel to the road. Their purpose is to
intercept seepage water and to drain any water
that may enter through the surface and drain out of
the base course.

Ground water drains are used for lowering the
water table and are situated on either side of the
road, running parallel to the alignment.
 Channels – open
drainage
Channels are conduits typically used to alter the
flow path of existing watercourse.

Advantages Disadvantages
Low construction costs, The space that is
Large discharge, occupied,

Storage capacities and The degree of
multiple uses in recreational, maintenance required,
aesthetic and sociological The possible abuse
fields. by unscrupulous
people.
 Culve
rts
Culvert: is defined as any conduit that conveys water
through an embankment.
Culverts are divided into two main types: flexible and
rigid.
 Flexible culverts are usually either thin-
walled steel pipes or galvanised
corrugated sections.
 Rigid culverts often comprise reinforced
concrete, precast units, cast iron or
vitrified clay.
 The slope of a culvert should conform to
the natural grade of the stream because
this produces the least silting or scouring.
 Culve
Factors govern the hydraulic
rts
capacity of a culvert:
 the depth of head and tail water
 the type of entrance. If the culvert
has a poorly designed entrance,
turbulence will occur at the inlet
and energy that would normally be
available for moving the water
through the culvert dissipates.
 the roughness of the interior walls
 the length of the culvert
 the fall through the culvert.
 Water
supply

Adequate water supply:
Reasonable access to a water source;
The availability of a sufficient quantity of
water
An acceptable quality of water.
END