Components of Water Supply.public health engineering and water management pdf
MuhammadRamzan757427
274 views
60 slides
May 06, 2024
Slide 1 of 60
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
About This Presentation
Public health engineering helping notes
Slide Content
LECTURE 9
•Collection Works
Dams ,Reservoir, Intake, Pumping station, Tube
wells.
•Purification Works
Sedimentation, Coagulation, Filtration, Disinfection,
Storage.
•Transmission Works
Conduits, Valves, Pumping Station, Gravity flow.
•Distribution Works
Pumping Station, Overhead reservoir, Feeders,
Mains, Pipes, Valves, Fire Hydrants.
Components of Water Supply
Scheme
Dams ,Reservoir, Intake, Pumping station, Tube
wells.
•Purification Works
Sedimentation, Coagulation, Filtration, Disinfection,
Storage.
•Transmission Works
Conduits, Valves, Pumping Station, Gravity flow.
•Distribution Works
Pumping Station, Overhead reservoir, Feeders,
Mains, Pipes, Valves, Fire Hydrants.
Components of Water Supply
Scheme
Future Water Requirement
•Selection of per capita water consumption(WC)
•Future population forecast
•Design period
•Selection of per capita water consumption(WC)
•Future population forecast
•Design period
Economical Period of Design
“Number of years in future for which proposed facility
would meet the demand of the community “
•Length /Life of structure↑ -Design Period ↑
•Ease of extension↑ -Design period ↓
•First cost↑ -Design period ↑
•Rate of interest↑ -Design period ↓
•Economy of scale ↑ -Design Period↑
•Lead time↑ -Design period↑
“Number of years in future for which proposed facility
would meet the demand of the community “
•Length /Life of structure↑ -Design Period ↑
•Ease of extension↑ -Design period ↓
•First cost↑ -Design period ↑
•Rate of interest↑ -Design period ↓
•Economy of scale ↑ -Design Period↑
•Lead time↑ -Design period↑
200 mm diameterwater supply pipe 1km long serves 3000 persons;
Cost =Rs 300000 ;Cost/head=Rs100
400 mm diameterwater supply pipe 1km long serves 12000 persons;
Cost =Rs 4800000 ;Cost/head=Rs 40
Economy of Scale
Cost =Rs 300000 ;Cost/head=Rs100
400 mm diameterwater supply pipe 1km long serves 12000 persons;
Cost =Rs 4800000 ;Cost/head=Rs 40
Economy of Scale
Design Periods & Design flows for various
Water Supply Facility
Facilities DesignPeriod Design Flow
Large dams, impounding
reservoirs, transmission
main (conduit)
25-50yrs Design capacity ofimpounding reservoir
Maximum daily demand
Conduits generally design for Maximum
daily consumption
Tube wells 5 yrs Peakhourly demand( without storage)
Maximum daily demand (with storage)
Water treatment plant 10-15 yrs Maximum daily demand
Pumping station 10 yrs Peak flow,Maximum+firedemand,Average
flow,minimumflow
Distribution system 25 yrs Maximumdaily flow+firedemand
Peak hourly demand+ fire demand
Water Supply Facility
Facilities DesignPeriod Design Flow
Large dams, impounding
reservoirs, transmission
main (conduit)
25-50yrs Design capacity ofimpounding reservoir
Maximum daily demand
Conduits generally design for Maximum
daily consumption
Tube wells 5 yrs Peakhourly demand( without storage)
Maximum daily demand (with storage)
Water treatment plant 10-15 yrs Maximum daily demand
Pumping station 10 yrs Peak flow,Maximum+firedemand,Average
flow,minimumflow
Distribution system 25 yrs Maximumdaily flow+firedemand
Peak hourly demand+ fire demand
Design Period
Problem1:Asmallcommunityhadapopulationof
65000and85000intheyearof1995and2005
respectively.Assumingageometricgrowthrateand
anaverageWCof300lit/cap/day.Calculatethe
designflowforthetreatmentplantandthe
transmissionmainfromcurrentyear.Selectan
appropriatevaluefordesignperiod.
Problem1:Asmallcommunityhadapopulationof
65000and85000intheyearof1995and2005
respectively.Assumingageometricgrowthrateand
anaverageWCof300lit/cap/day.Calculatethe
designflowforthetreatmentplantandthe
transmissionmainfromcurrentyear.Selectan
appropriatevaluefordesignperiod.
Design Period
Problem2:Thepresentpopulationofacommunity
is160000increasingatageometricgrowthrateof
0.043peryr.Thepresentwaterrequirementofthe
communityarefullymetbyanumberoftubewells
installedinthecity.TheaverageWCis350l/c/d
usingadesignperiodof15yrs.Calculatethe
numberofadditionaltube-wellsof3.4m
3
/min
capacitytomeetthedemandofdesignperiod.
Problem2:Thepresentpopulationofacommunity
is160000increasingatageometricgrowthrateof
0.043peryr.Thepresentwaterrequirementofthe
communityarefullymetbyanumberoftubewells
installedinthecity.TheaverageWCis350l/c/d
usingadesignperiodof15yrs.Calculatethe
numberofadditionaltube-wellsof3.4m
3
/min
capacitytomeetthedemandofdesignperiod.
Sourcesof Water
Rainwater
dissolution of
CO
2-H
2CO
3
Surface water
suspended solids(silt
clay) inorganic salts,
oils, organics,
nutrients, pesticides,
pathogens from
municipal, agricultural
runoff
Groundwater
Depth>35m
safe wrtmicrobial contaminants
Generally hard water
Rainwater
dissolution of
CO
2-H
2CO
3
Surface water
suspended solids(silt
clay) inorganic salts,
oils, organics,
nutrients, pesticides,
pathogens from
municipal, agricultural
runoff
Groundwater
Depth>35m
safe wrtmicrobial contaminants
Generally hard water
1.Rain water
•Generally satisfactory
•Dissolution of carbon dioxide(H2CO3)
•Affected by collection system and storage conditions.
2.Surface water
•Include rivers, streams, lakes
•Generally soft water but may contains;
Significant load of suspended solids(SS) from land
erosion.
Color , odour(decaying vegetation)
Sourcesof Water
•Generally satisfactory
•Dissolution of carbon dioxide(H2CO3)
•Affected by collection system and storage conditions.
2.Surface water
•Include rivers, streams, lakes
•Generally soft water but may contains;
Significant load of suspended solids(SS) from land
erosion.
Color , odour(decaying vegetation)
Sourcesof Water
Heavy metals, inorganic salts, oils, organic
compounds, nutrients, pesticides, pathogens from
municipal, industrial and agricultural runoffs.
Lead, acid deposition from atmosphere.
Surface waters require elaborate treatment for use
as drinking water supplies.
3.Groundwater
•Ground water are generally safe with respect to
microbial concentration.
•Rich in total dissolved solids
•May contains naturally occurring subsoil heavy
metals such as As, F, Fe, Mn
Sources of Water
compounds, nutrients, pesticides, pathogens from
municipal, industrial and agricultural runoffs.
Lead, acid deposition from atmosphere.
Surface waters require elaborate treatment for use
as drinking water supplies.
3.Groundwater
•Ground water are generally safe with respect to
microbial concentration.
•Rich in total dissolved solids
•May contains naturally occurring subsoil heavy
metals such as As, F, Fe, Mn
Sources of Water
•Groundwatermaybepolluteddueto:
Seepageofagriculturalchemicals(NO
3,Pesticides,
Insecticides)
Sanitarylandfillleachates
Microbialpollutionintroducedbysoakagepit
Industrialwasteimpoundsmayincreaseheavy
metals,saltandorganicmatterconcentrations
•Groundwatergenerallyconsideredashardwater.
•Groundwatersmostlyrequireminimaltreatment
(disinfectiononly)foruseasdrinkingwater.
Sources of Water
Seepageofagriculturalchemicals(NO
3,Pesticides,
Insecticides)
Sanitarylandfillleachates
Microbialpollutionintroducedbysoakagepit
Industrialwasteimpoundsmayincreaseheavy
metals,saltandorganicmatterconcentrations
•Groundwatergenerallyconsideredashardwater.
•Groundwatersmostlyrequireminimaltreatment
(disinfectiononly)foruseasdrinkingwater.
Sources of Water
Collection of Surface Water
Intake
•Device or structure placed in a surface water
source to permit the withdrawal of water from
that source
Parts of intake: consists of three parts
1.An opening or strainer or grating through which
the water enters
2.A conduit , to convey water to sump
3.A sump or well from where water is pumped to
treatment plant.
Intake
•Device or structure placed in a surface water
source to permit the withdrawal of water from
that source
Parts of intake: consists of three parts
1.An opening or strainer or grating through which
the water enters
2.A conduit , to convey water to sump
3.A sump or well from where water is pumped to
treatment plant.
Types of Intake
1.Single port:
To draw water from a constant /fixed depth
2.Multi port:
For selective draft for various depths
Factors Affecting Intake Type
•Source of supply:
River , lake Single port
Reservoir Multi port
Collection of Surface Water
1.Single port:
To draw water from a constant /fixed depth
2.Multi port:
For selective draft for various depths
Factors Affecting Intake Type
•Source of supply:
River , lake Single port
Reservoir Multi port
Collection of Surface Water
Factors affecting Intake Structure
Water Availability
Sediment Transport
Environmental Regulation
Climatic Conditions
Initial and Maintenance Dredging
Operation and Maintenance
Water Availability
Sediment Transport
Environmental Regulation
Climatic Conditions
Initial and Maintenance Dredging
Operation and Maintenance
Reservoir intake
Lake intake(single port)
River intake (single port)
Intakes
•To be located away from pollution source
•Adequate submergence of the ports to avoid floating
debris and meet navigational requirements.
•Adequate elevation of conduit from the stream/lake
bed to avoid bed debris
•Entering velocity in conduit not to exceed 0.15 m/sec
to avoid trapping of excessive floating material,
sediment, ice, or fish.
Technical & Environmental Considerations
•To be located away from pollution source
•Adequate submergence of the ports to avoid floating
debris and meet navigational requirements.
•Adequate elevation of conduit from the stream/lake
bed to avoid bed debris
•Entering velocity in conduit not to exceed 0.15 m/sec
to avoid trapping of excessive floating material,
sediment, ice, or fish.
Technical & Environmental Considerations
Technical & Environmental Considerations
Dams
•To be constructed at a location with a narrow gorge(narrow
entrance)
•Provision of solid foundation design
•Adequate height to provide required storage to meet draft
requirements at maximum daily flow.
•Upstream area to be free from pollution
•No discharges of industrial , municipal, and agricultural
runoffs.
•Watershed area to be heavily forested to avoid siltation in the
reservoir.
Dams
•To be constructed at a location with a narrow gorge(narrow
entrance)
•Provision of solid foundation design
•Adequate height to provide required storage to meet draft
requirements at maximum daily flow.
•Upstream area to be free from pollution
•No discharges of industrial , municipal, and agricultural
runoffs.
•Watershed area to be heavily forested to avoid siltation in the
reservoir.
Components of Water Distribution System
•Pipes
•Fire Hydrants
•Valves
•Service Reservoirs (OHR)
•Pipes
•Fire Hydrants
•Valves
•Service Reservoirs (OHR)
Water Distribution System
Gravity distribution
•Natural slope, spring at peak (Muree, D.G.Khan)
•Economical and easy to install
•Site specific
•For fire protection, generally pumps are used.
Gravity distribution
•Natural slope, spring at peak (Muree, D.G.Khan)
•Economical and easy to install
•Site specific
•For fire protection, generally pumps are used.
Distribution by pump w/o storage
(Direct Pumping)
•Not practicable
•High electricity cost
•Operator role important(constant attendance)
•Power /tube well or fire breakdown problem
•Pressure variation
•Pumps are design at peak hourly flow
•Several pumps to conform varying demand
(Direct Pumping)
•Not practicable
•High electricity cost
•Operator role important(constant attendance)
•Power /tube well or fire breakdown problem
•Pressure variation
•Pumps are design at peak hourly flow
•Several pumps to conform varying demand
Pump with storage
•Excess water pumped during periods of low
consumption stored in OHR
•High consumption periods water drawn out to
augment pumped water
•Constant pumping rate
•Economical as pumping rate max. daily flow
instead of peak hourly flow
•More reliable due to fire fighting reserve
•Excess water pumped during periods of low
consumption stored in OHR
•High consumption periods water drawn out to
augment pumped water
•Constant pumping rate
•Economical as pumping rate max. daily flow
instead of peak hourly flow
•More reliable due to fire fighting reserve
Pump with storage
Layoutwater distribution
Dead End or Tree System
•Irregularly developed cities
Advantages
•Easy design
•Less valve to cut off
supplies
Disadvantages
•Stagnation of water at
dead ends
•Large portions of cities for
repairs to be cut off
Dead End or Tree System
•Irregularly developed cities
Advantages
•Easy design
•Less valve to cut off
supplies
Disadvantages
•Stagnation of water at
dead ends
•Large portions of cities for
repairs to be cut off
Grid –Iron System
•No stagnation
•More valves(costly)
•Difficult to design
•Expensive option
•More common in developed countries
Layout water distribution
•No stagnation
•More valves(costly)
•Difficult to design
•Expensive option
•More common in developed countries
Layout water distribution
Types of water supply
Continuous-fire demand
•No infiltration
•More water use
Intermittent
•Infiltration/Seepage (more chance of contamination)
•Storing water in dirty containers
•Taps carelessly kept open
•Consumers waste stored water to get fresh water
Pipelines are subjected to vacuum condition after supply hours, which can cause groundwater infiltration into the pipelines with
contamination of the supply or pipes deformation
Continuous-fire demand
•No infiltration
•More water use
Intermittent
•Infiltration/Seepage (more chance of contamination)
•Storing water in dirty containers
•Taps carelessly kept open
•Consumers waste stored water to get fresh water
Pipelines are subjected to vacuum condition after supply hours, which can cause groundwater infiltration into the pipelines with
contamination of the supply or pipes deformation
Pipe Distribution System
Primary Feeders
•Main skeleton
•Water pumping to OHR and various parts of city
•In cities form loops, about 1 km apart .
•Looping allows continuous flow and adequate fire
flows.
•Provided with air relief valve & blow off valve
•Size >300mm ϕ
Primary Feeders
•Main skeleton
•Water pumping to OHR and various parts of city
•In cities form loops, about 1 km apart .
•Looping allows continuous flow and adequate fire
flows.
•Provided with air relief valve & blow off valve
•Size >300mm ϕ
Secondary feeder
•Carry water from Primary feeder to cater for
normal supplies +firefighting(12”-Lahore)
•Smaller loops within loops of primary feeder
•In cities these are few blocks apart
•sizes are 200mm,250,300mm ϕ
Pipe Distribution System
•Carry water from Primary feeder to cater for
normal supplies +firefighting(12”-Lahore)
•Smaller loops within loops of primary feeder
•In cities these are few blocks apart
•sizes are 200mm,250,300mm ϕ
Pipe Distribution System
Pipe Distribution System
Small distribution mains/Tertiary Feeder
•Form grid over areas and supply water to
fire hydrant and domestic supply lines (150
mm ϕ)
Domestic supply lines
•Generally the sizes are <100-150 mm ϕ
Small distribution mains/Tertiary Feeder
•Form grid over areas and supply water to
fire hydrant and domestic supply lines (150
mm ϕ)
Domestic supply lines
•Generally the sizes are <100-150 mm ϕ
Consideration pipe layout
•Right of way: not intersect private property
•Not on mines/ military remains
•Not damage existing infrastructure(telephone lines,
sewerage pipes etc.
•For high points use air release valves and low points
blow off valve
•Avoid point of inflection
•When crossing river /stream better to attach with
bridge or if passing through stream keep narrowest
section or widest one if u want to bury pipes
•Concrete blocks at point of inflection(thrust blocks)
•Right of way: not intersect private property
•Not on mines/ military remains
•Not damage existing infrastructure(telephone lines,
sewerage pipes etc.
•For high points use air release valves and low points
blow off valve
•Avoid point of inflection
•When crossing river /stream better to attach with
bridge or if passing through stream keep narrowest
section or widest one if u want to bury pipes
•Concrete blocks at point of inflection(thrust blocks)
Laying of Distribution System
Excavation
•Min depth :is 1 m to protect the pipe against
traffic load
•Trench width: Sufficient width be provided for
proper laying & jointing of pipes.
Pipe Trench width
2” 1.5’
3” 2’
4” 2’
6” 2’
Excavation
•Min depth :is 1 m to protect the pipe against
traffic load
•Trench width: Sufficient width be provided for
proper laying & jointing of pipes.
Pipe Trench width
2” 1.5’
3” 2’
4” 2’
6” 2’
Laying of Distribution System
Laying & Jointing
•This include removal of pipes from vehicle,
conveying it to the storage in a yard or at street &
placing it in a trench & making proper joints.
Thrust blocks
•PCC blocks are provided at all tees, bends & dead
ends to nullify water thrust
Back Filling
•Back filling material should be free from large
stones.
Laying & Jointing
•This include removal of pipes from vehicle,
conveying it to the storage in a yard or at street &
placing it in a trench & making proper joints.
Thrust blocks
•PCC blocks are provided at all tees, bends & dead
ends to nullify water thrust
Back Filling
•Back filling material should be free from large
stones.
OVER HEAD RESERVOIR
Terminology
Yield
The portion of precipitation on the watershed that
can be collected for use.
Safe Yield
It is the minimum yield recorded for given past
period.
Draft
It is the intended or actually quantity of water
drawn for use.
Yield
The portion of precipitation on the watershed that
can be collected for use.
Safe Yield
It is the minimum yield recorded for given past
period.
Draft
It is the intended or actually quantity of water
drawn for use.
Capacity of Overhead Reservoir
Objective of storage
•Uniform pumping rate/day or desired
pumping rate
•Equalize demand over a period of high use or
when pumping discontinued
•Emergency(fire,tubewellchanges,electrical
breakdown)
Objective of storage
•Uniform pumping rate/day or desired
pumping rate
•Equalize demand over a period of high use or
when pumping discontinued
•Emergency(fire,tubewellchanges,electrical
breakdown)
•Storage capacity=equalizing storage(15-30%
Max day.)+firefighting(2-10hrs)
+emergency(variable)
•Public Health engineering Department (PHED)
recommended storage capacities for
Electric pumps –1/6 th of avg. daily
consumption
Diesel Pumps -¼ th of avg. daily
consumption
Capacity of Overhead Reservoir
Max day.)+firefighting(2-10hrs)
+emergency(variable)
•Public Health engineering Department (PHED)
recommended storage capacities for
Electric pumps –1/6 th of avg. daily
consumption
Diesel Pumps -¼ th of avg. daily
consumption
Capacity of Overhead Reservoir
Determination of Required Equalization
Storage
Mass Diagram
•Graphical representation for finding the storage
in reservoir.
•Also called Ripple diagram
•Mass diagram present the accumulated total
discharge as a function of time.
•For mass diagram records of stream flow for
substantial period of time is required generally
more than 30 yrs.
Storage
Mass Diagram
•Graphical representation for finding the storage
in reservoir.
•Also called Ripple diagram
•Mass diagram present the accumulated total
discharge as a function of time.
•For mass diagram records of stream flow for
substantial period of time is required generally
more than 30 yrs.
Mass Diagram
Draft
Draft
Reservoir Storage
Problem 3: From the following record of average monthly stream
flows:
1)Determine the require reservoir size to provide a uniform flow(draft) of
11000 m
3
/day
2)What will be the safe yield of the year in with storage reservoir for the
year.
MonthFlow(m
3
X10
6
)MonthFlow(m
3
X10
6
)Month Flow
(m
3
X10
6
)
1 0.18 8 0.08 15 1.01
2 1.02 9 0.07
3 1.32 10 0.04
4 0.51 11 0.1
5 0.87 12 0.26
6 0.67 13 0.2
7 0.19 14 1.10
Problem 3: From the following record of average monthly stream
flows:
1)Determine the require reservoir size to provide a uniform flow(draft) of
11000 m
3
/day
2)What will be the safe yield of the year in with storage reservoir for the
year.
MonthFlow(m
3
X10
6
)MonthFlow(m
3
X10
6
)Month Flow
(m
3
X10
6
)
1 0.18 8 0.08 15 1.01
2 1.02 9 0.07
3 1.32 10 0.04
4 0.51 11 0.1
5 0.87 12 0.26
6 0.67 13 0.2
7 0.19 14 1.10
Mathematical
•Add the highest positive figure to the highest
negative figure, ignoring the sign
Determination of Required Equalization Storage
•Add the highest positive figure to the highest
negative figure, ignoring the sign
Determination of Required Equalization Storage
Reversior Storage
Time Consumption
12MN-4AM 1.00
4AM-8AM 3.00
8AM-12N 3.55
12N-4PM 3.25
4PM-8PM 2.50
8PM-12MN 1.50
Problem 4:Water consumption during a typical day in a
city is given below in a table. Determine the equalizing
storage if pumping is uniformly extended over 4AM to
4PM.
Time Consumption
12MN-4AM 1.00
4AM-8AM 3.00
8AM-12N 3.55
12N-4PM 3.25
4PM-8PM 2.50
8PM-12MN 1.50
Problem 4:Water consumption during a typical day in a
city is given below in a table. Determine the equalizing
storage if pumping is uniformly extended over 4AM to
4PM.
TYPES OF WATER SUPPLY
PIPES
PIPES
Water Supply Pipes
•Various types of pipes are available for the
construction of water supply network.
•The following points should be considered for
selection;
Carrying capacity
Durability
First cost
Maintenance cost
Type of water to be conveyed
•Various types of pipes are available for the
construction of water supply network.
•The following points should be considered for
selection;
Carrying capacity
Durability
First cost
Maintenance cost
Type of water to be conveyed
Types of Water Supply Pipes
1.Cast Iron Pipes:
•Most widely used for city water supply
•Average life of pipes 100 yrs
•Corrosion (tuberculation)may reduce its capacity by
70%,must be lined with cement or bitumen
•Roughness coefficient (C)for new pipe is 130
•Roughness coefficient (C) for old pipe is 100
1.Cast Iron Pipes:
•Most widely used for city water supply
•Average life of pipes 100 yrs
•Corrosion (tuberculation)may reduce its capacity by
70%,must be lined with cement or bitumen
•Roughness coefficient (C)for new pipe is 130
•Roughness coefficient (C) for old pipe is 100
2.Steel Pipes:
•Contains less carbon than cast iron pipe
•Average life is 25-50 yrs
•Frequently used for trunk mains
•Difficult to make connections, hence seldom used
for water distribution
•Much stronger and lighter than cast iron pipes
•Cheaper than cast iron pipes
•Cannot withstand vacuum, hence collapse
•Highly susceptible to corrosion, hence high
maintenance charges required.
Types of Water Supply Pipes
•Contains less carbon than cast iron pipe
•Average life is 25-50 yrs
•Frequently used for trunk mains
•Difficult to make connections, hence seldom used
for water distribution
•Much stronger and lighter than cast iron pipes
•Cheaper than cast iron pipes
•Cannot withstand vacuum, hence collapse
•Highly susceptible to corrosion, hence high
maintenance charges required.
Types of Water Supply Pipes
3.Ductile Pipes:
•Similar to CI pipes except increased ductility(it is the
property of a metal of being capable to be drawn
out into wire)
•Ductile iron is produced by adding a controlled
amount of Mg into molten iron of low sulphur and
phosphorus content
•Stronger,tougherandmoreelasticthanCI.
•More expensive than CI.
Types of Water Supply Pipes
•Similar to CI pipes except increased ductility(it is the
property of a metal of being capable to be drawn
out into wire)
•Ductile iron is produced by adding a controlled
amount of Mg into molten iron of low sulphur and
phosphorus content
•Stronger,tougherandmoreelasticthanCI.
•More expensive than CI.
Types of Water Supply Pipes
4.Galvanized Iron Pipes:
•Produced by dipping CI pipes in molten zinc
•Resistant to corrosion
•Mainly used for plumbing
•Maximum dia6 inches
5.Concrete Pipes:
•Usual size of RCC pipes 400 mm and above
•Not subjected to corrosion
•Manufactured at or near site
•Average life of pipe is 75 yrs
•Roughness coefficient is between 138 to 152
Types of Water Supply Pipes
•Produced by dipping CI pipes in molten zinc
•Resistant to corrosion
•Mainly used for plumbing
•Maximum dia6 inches
5.Concrete Pipes:
•Usual size of RCC pipes 400 mm and above
•Not subjected to corrosion
•Manufactured at or near site
•Average life of pipe is 75 yrs
•Roughness coefficient is between 138 to 152
Types of Water Supply Pipes
6.Asbestos Cement Pipes:
•Sizes available between 100mm-600 mm
•Average life –30 yrs
•Immune to actions of acids, salts, soil, corrosion
•Less pumping cost due to less friction
•Roughness coefficient is equal to 140
7.Poly vinyl chloride Pipes:
•Mainly used for domestic plumbing
•Easy to install , easy to handle
•Cheaper in material cost
•Weak to sustain load, piling
•Only available upto350mm diasize
•Expected life –25 yrs
•PVC becomes brittle when placed in sunlight
Types of Water Supply Pipes
•Sizes available between 100mm-600 mm
•Average life –30 yrs
•Immune to actions of acids, salts, soil, corrosion
•Less pumping cost due to less friction
•Roughness coefficient is equal to 140
7.Poly vinyl chloride Pipes:
•Mainly used for domestic plumbing
•Easy to install , easy to handle
•Cheaper in material cost
•Weak to sustain load, piling
•Only available upto350mm diasize
•Expected life –25 yrs
•PVC becomes brittle when placed in sunlight
Types of Water Supply Pipes
Valves
Purpose:
1.Regulate flow
2.Regulate pressure
3.Cut off supply for repair purpose
Location of Valves:
•Two valves at each intersection
•One valve at fire hydrant
•One valve after each 400m length of pipe
•On average 8 valves/km of main
Purpose:
1.Regulate flow
2.Regulate pressure
3.Cut off supply for repair purpose
Location of Valves:
•Two valves at each intersection
•One valve at fire hydrant
•One valve after each 400m length of pipe
•On average 8 valves/km of main
Types of Valves
1.Gate Valve(sluice valve)
•Used to shut off water supply
mains for repair
•Generally placed at street corners
where lines intersect.
2.Global Valve
•Used in the plumbing system on
smaller pipes.
•They create lot of head loss
1.Gate Valve(sluice valve)
•Used to shut off water supply
mains for repair
•Generally placed at street corners
where lines intersect.
2.Global Valve
•Used in the plumbing system on
smaller pipes.
•They create lot of head loss
3.Check Valve
•Uni-directional flow
•Discharge side of pump to
reduce water hammer effect
(pumping stations)
Types of Valves
•Uni-directional flow
•Discharge side of pump to
reduce water hammer effect
(pumping stations)
Types of Valves
4.Butterfly Valve
•Used in filter plants and high pressure distribution
systems.
•Shut off very slowly to avoid water hammer.
Types of Valves
•Used in filter plants and high pressure distribution
systems.
•Shut off very slowly to avoid water hammer.
Types of Valves
5.Pressure Regulating Valve
•Reduce pressure d/s side to any desired
magnitude(60 psi)
•Spring and adjustable diaphragm in order to increase
or decrease the water pressure within the water
supply service
Types of Valves
•Reduce pressure d/s side to any desired
magnitude(60 psi)
•Spring and adjustable diaphragm in order to increase
or decrease the water pressure within the water
supply service
Types of Valves
6.Air Relief Valve
•It allows the accumulated air in the pipe to escape
•It also allows the external air to enter the pipe to
break the vacuum.
•Placed at high points of the line
Types of Valves
•It allows the accumulated air in the pipe to escape
•It also allows the external air to enter the pipe to
break the vacuum.
•Placed at high points of the line
Types of Valves
7.Blow off Valve
•Used to drain a line, or to remove
accumulated sediments
•Located at low points.
.
Types of Valves
•Used to drain a line, or to remove
accumulated sediments
•Located at low points.
.
Types of Valves
8. Altitude Valve
•Close automatically a supply line to an
elevated tank when full
•differential in forces between a spring load
and the water level in the reservoir.
•When the force of the spring is overcome by
the force of the reservoir head, the pilot
closes the main valve
•Desiredhigh water level set by
adjusting the spring force
Types of Valves
•Close automatically a supply line to an
elevated tank when full
•differential in forces between a spring load
and the water level in the reservoir.
•When the force of the spring is overcome by
the force of the reservoir head, the pilot
closes the main valve
•Desiredhigh water level set by
adjusting the spring force
Types of Valves
Fire hydrants
•Atleast2 hose outlets and
larger pumper outlet
•Located at street intersection
1-2 m from the edge of road
1m3/min
0.5 m
•Atleast2 hose outlets and
larger pumper outlet
•Located at street intersection
1-2 m from the edge of road
1m3/min
0.5 m
Tags
Download
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 274
- Slides 60
- Age 583 days
Related Slideshows
36
Clinical approach Dyspnoea A simple and practical approach.pptx
ShajahanPS
31 views
238
Cancer Awareness therapy for public by Dr Kanhu Charan Patro
kanhucpatro
31 views
41
Prof Satyadas Memorial oration Kozhikode.pptx
ShajahanPS
27 views
26
Viral Conjunctivitis and it;s managment.pptx
ZaidAzhar
39 views
30
Essential Thrombocythemia 15 Years of Experience at the Hematology Department, Algies, Algeria.pdf
sbelakehal
35 views
10
Hypertension sign symptoms cmdt style with regime
androiddabest
36 views