TECHNICAL PAPER # 28
UNDERSTANDING WATER SUPPLY:
GENERAL CONSIDERATIONS
By
Joe Remmers
Technical Reviewers
Dr. F. O. Blackwell
Morton S. Hilbert, P.E.
Published By
VITA
1600 Wilson Boulevard, Suite 500
Arlington, Virginia 22209 USA
Tel: 703/276-1800 . Fax:703/243-1865
Internet: pr-info@vita.org
Understanding Water Supply: General Considerations
ISBN: 0-86619-231-X
[C]1985, Volunteers in Technical Assistance
PREFACE
This paper is one of a series published by Volunteers in
Technical
Assistance to provide an introduction to specific
state-of-the-art
technologies of interest to people in developing countries.
The papers are intended to be used as guidelines to help
people choose technologies that are suitable to their
situations.
They are not intended to provide construction or
implementation
details. People are urged to contact VITA or a similar
organization
for further information and technical assistance if they
find that a particular technology seems to meet their needs.
The papers in the series were written, reviewed, and
illustrated
almost entirely by VITA Volunteer technical experts on a
purely
voluntary basis. Some 500 volunteers were involved in the
production
of the first 100 titles issued, contributing approximately
5,000 hours of their time. VITA staff included Maria
Giannuzzi
as editor, Julie Berman handling typesetting and layout, and
Margaret Crouch as project manager.
The author of this paper, VITA Volunteer Joe Remmers, is a
civil
engineer who designs and constructs water and wastewater
facilities
for Black & Veatch Construction Engineers. He has
prepared
plans and specifications for various construction projects
in
Saudi Arabia. The reviewers are also VITA volunteers. Dr.
F.O.
Blackwell is an associate professor in environmental health
with
the East Carolina University School of Allied Health. He has
worked as a health and sanitation adviser with the United
States
Agency for International Development in Pakistan, and has
taught
at the American University of Beirut, Lebanon School of
Public
Health. Morton S. Hilbert, P.E., is chairman and professor
in the
department of environmental and industrial health at the
University
of Michigan School of Public Health. He is a registered
professional engineer and has worked in the field of environmental
health in 20 countries in Africa, South America, Central
America, and Asia.
VITA is a private, nonprofit organization that supports
people
working on technical problems in developing countries. VITA
offers
information and assistance aimed at helping individuals and
groups to select and implement technologies appropriate to
their
situations. VITA maintains an international Inquiry Service,
a
specialized documentation center, and a computerized roster
of
volunteer technical consultants; manages long-term field
projects;
and publishes a variety of technical manuals and papers.
UNDERSTANDING WATER SUPPLY--GENERAL CONSIDERATIONS
by VITA Volunteer Joe Remmers
I. INTRODUCTION
Water supply systems have been a vital part of human life
since
before recorded history. Early "systems" consisted
of no more
than simply drawing water out of a river or lake with a jar
or
bowl. Later, aqueducts were built to move water to more
desirable
locations. Such was the case in ancient Egyptian societies.
The
Romans were known to have developed aqueducts for conveying
water
for use within their cities. Cast iron piping was reportedly
used
in Europe in the seventeenth century. Hand pumps appeared
for the
first time toward the latter half of the eighteenth century.
Water system technology changed drastically during the
Industrial
Revolution when engine- and motor-driven pumps were
developed.
Chlorine was discovered to be an effective germ-killing
agent and
modern pipe manufacturing techniques were invented. Today,
water
systems around the world provide safe drinking water for
millions
of people.
In those parts of the world not served by water systems,
however,
inadequate water supplies continue to be a major problem.
The
World Health Organization has estimated that approximately
1,100
million people do not have access to safe and adequate water
supplies.
In response to this urgent need for improved water supply
and sanitation, the United Nations declared the 1980s to be
the
International Drinking Water and Sanitation Decade. The goal
is
to provide safe water in sufficient quantity for all the
world's
people by 1990.
Improved water systems can help to provide adequate supplies
of
safe drinking water in these regions. "Safe" water
is water that
does not contain disease-producing organisms e.g., cholera,
typhoid fever, dysentery, worms) and does not contain
harmful
chemicals (e.g., arsenic, lead). The reasons for developing
a
water supply system are simple: to transport water from its
source; to treat it so that it is safe to drink; to
distribute it
to wherever it is needed; and to store it whenever necessary
for
future use.
A properly designed and constructed water system, which is
operated
and maintained correctly, will provide a safe and adequate
water supply for the people of the district the system
supports.
In addition to furnishing safe drinking water for a
community, a
water supply system can provide irrigation water and water
for
industrial purposes. A safe, adequate, and economical source
of
water for agricultural and industrial uses could stimulate
the
economic growth and overall well-being of a particular
region.
The purpose of this paper is to provide basic information
and
data for those individuals responsible for developing a
safe,
economical, and practical water system for their
communities. It
examines the various factors that must be considered before
development of a water system is started. More detailed
information
can be found in the other papers within VITA's
"Understanding
Water Supply" series. These other papers cover the
following
topics:
Water Supply--sources
Water Supply--treatment
Water Supply--storage
Water Supply--distribution
This paper is not intended to serve as a design manual; for
particular
design problems, the services of specially trained persons
should be sought.
II. COSTS AND BENEFITS OF WATER SYSTEMS
The construction and operation of a water supply system can
be
costly, so the benefits of constructing such a system must
be
properly assessed. Usually, the benefits far outweigh the
costs.
Having a readily available source of water provides economic
benefits because people who formerly needed to carry water
for
long periods every day will be free to attend to other
matters
such as farming, trade, or business. The most important
benefit
of a safe and adequate water supply is the prevention of
waterborne
diseases that are present where water is not good.
The most expensive items in a water supply system would be
heavy
equipment such as pumps, motors, and treatment equipment.
Next
would be buildings and tanks. Depending on the size of the
system
and type of piping material used, the least expensive
component
would be the distribution piping.
The cost of labor must also be considered. Community members
may
wish to do the job themselves to avoid having to hire
outside
help. But this approach may have a hidden cost if it
distracts
people from their primary job, farming for example, and
causes
productivity to go down. But community projects are working
well
in many areas, and the inherent pride of ownership may
offset
other costs.
III. SYSTEM DESCRIPTION
CHARACTERISTICS
Water systems consist of the following basic
components: (1) a
water source, such as a lake, stream, spring, river, or
underground
aquifer; (2) a method of transportation from the source to
the user, such as a canal system or pump/pipe system; (3) a
method of treatment, such as sedimentation, filtration, or
disinfection;
and (4) a method of storage, such as a closed tank,
standpipe, or a protected reservoir. A system does not
necessarily
need all of the above components. Required components would
depend on the particular needs of the community served.
RESOURCES
The resources required for the development of a water system
depend on the complexity of the system. In general, a system
should be kept as simple as possible to minimize the strain
on
available resources. The resources required to develop a
water
supply system are discussed below.
Materials
Materials that are needed for building a water system may
include
concrete for storage tanks and treatment facilities; steel,
cast
iron, copper, and plastic (among other materials) for
piping; and
other construction materials, such as wood, brick, mortar
and
clay, to build units to house treatment and pumping
facilities.
Hypochlorite or chlorine gas will be needed for disinfection
of a
newly-constructed system. In the event of the threat of
disease,
a continuing supply of these chemicals should be available
to
disinfect the daily water supply.
Labor
A substantial amount of hand labor is required to construct
a
water system. The number of laborers depends on the
availability
of equipment--the more heavy machinery available the less
need
for manual laborers. Labor would be needed to construct dams
or
canals, to dig trenches about .3 to 1 meter deep, to carry
and
lay pipe, and to construct treatment facilities, pump
houses, and
tanks. Most of the required labor could be unskilled, but
some
semi-skilled or skilled workers would also be needed. Pipe
laying
techniques can be learned rather quickly, but construction
of
buildings and tanks is more complex and must be learned over
a
period of time. If an area contains very few skilled
individuals,
a training program may have to be established before
undertaking
construction projects.
Equipment
Equipment as simple as a shovel or as complicated as
power-operated
heavy machinery (such as a backhoe) can be used. A
community should use what is available and affordable to
them.
For instance, when only shovels are available, the project
would
be labor-intensive, and probably less costly. It would also
probably take longer. If backhoes, bulldozers, or trenchers
are
available and affordable, the project would be
equipment-intensive.
It would probably also be more costly, but would likely be
finished more quickly than a labor-intensive system.
To construct treatment works, pump houses, and tanks,
concrete
mixers, wheelbarrows, scaffolds, and assorted hand tools
would be
helpful. Tanks and facilities constructed of steel would
require
more complex equipment such as welding kits, cranes, and
precision
measuring instruments.
Components of the system include equipment such as pumps,
engines,
motors, valves, gauges, screens, filters, flocculators,
sludge collectors, and chlorinators. Again, not all this
equipment
would necessarily appear in one system--the amount depends
on the system's level of complexity.
Energy
Energy is needed to run any water system. Energy is required
to
pump water up from aquifers, to move it from the treatment
plant
to storage tanks at higher elevations, and to send it
through the
distribution system. This energy can come from
gravity--water
flowing downhill--or it can come from human
resources--applying
mechanical motion to a hand pump. Energy can also be derived
from
the wind, the sun, fossil fuels, or from the water itself,
as
with a hydraulic ram or water wheel. If electric generating
plants are in the area, this source of energy should be
investigated.
Energy is costly, so the most economical and reliable
source should be considered.
Design
Before any effort is made to develop a water system, the
services
of competent design professionals should be sought. These
professionals
are typically civil or mechanical engineers, or other
water resource specialists. Contractors who are in the water
line
construction business, as well as plumbers and pipefitters,
could
also be of assistance. Design professionals can help with
sizing
a water system, determining water pressures, determining the
right treatment methods to use, designing structures, and
estimating
construction and operating costs.
Testing
To ensure that a water supply is safe for drinking, some
method
of periodic testing should be provided for. If the water
supply
is suspected as the source of a disease outbreak, additional
bacteriological testing is required. Laboratories that can
check
water for both bacteriological and chemical safety are
generally
operated by government health agencies. Field kits and
equipment
for bacteriological testing are also available and local
persons
can be trained to use them. In the event a laboratory is not
available, these kits should be used for testing water
supplies.
Special Circumstances
The community owning a water supply system must have
contingency
plans in case certain events occur. Such an event might be
the
outbreak of a waterborne disease. Or, the water source could
dry
up, as in the event of a drought. Contingency plans should
include
alternate sources of water or an emergency tank or
reservoir.
MAINTENANCE REQUIREMENTS
Water pipes or mains, when properly installed, do not often
require maintenance. Occasionally, a line may break,
requiring a
crew to go out and repair it. Valves require some
maintenance.
They should be operated periodically to avoid the build-up
of
mineral deposits.
The greatest maintenance requirements are found at the
pumping
and/or treatment works. Any time there are moving parts,
mechanical
breakdowns will occur and experienced mechanics will be
needed to fix them. Filters at the treatment works will need
periodic cleaning, as will any settling basins. Routine
checks
and inspections as well as data collection and recording
(pumping
records, electricity used, chemicals used, etc.) must be
carried
out.
Laboratory tests for bacteria (coliform) must be done at
regular
intervals (daily, weekly, or monthly, depending on the
number of
Persons served). Chemical testing needs to be done only
yearly
unless problems are suspected.
Maintenance is an ongoing expense. It must be considered in
the
early cost/benefit analysis and provided for as resources
are
allocated. Some communities cover maintenance costs through
a
system of user fees.
IV. DESIGNING THE SYSTEM RIGHT FOR YOU
DESIGN CONSIDERATIONS
The first consideration in designing a water supply system
is to
determine the total quantity of water the system would be
required
to deliver. Water quantities are usually based on the
number of persons a community's system is required to serve.
A
commonly accepted water demand factor used in practice today
is
550 liters per person per day, a figure that allows for some
commercial and laundry use. In areas where survival is
threatened
by water shortages, a smaller amount per person should be
considered
so that water can be provided to more people. Under extreme
conditions, the minimum allotment should be 90 liters per
person
per day.
The figure per person should then be multiplied by the total
population of the community to arrive at the average daily
demand
(ADD). The peak flow, defined as the consumption during the
time
of heaviest use, should be used to determine the volume of
storage
required and the pipe sizes needed in the system. The peak
flow can be estimated by multiplying the ADD by 2.5.
The second consideration in designing a water system is to
determine
the pressure requirements at various points in the system.
The pressure requirements affect energy costs, and,
therefore, a
good portion of operating costs. Calculating the pressures
in the
system also gives an indication of the type and size of
pumps
that may be required. A piped system should, ideally, be
under
positive pressure at all times to minimize any infiltration
of
contaminated water, and thus prevent disease.
SCALE
Water systems can be constructed to serve large regions such
as
entire countries or cities; they can serve small
communities; or
they can serve only a single family residence. In some
cases, a
centralized system having only a few sources of supply and
distributing
water areawide may be preferable to many small systems
serving individual communities or residences. Because its
main
waterworks can be monitored more easily, the centralized
system
has lower operating costs and better control over the safety
of
the water. In other cases, smaller systems may be a better
choice. The choice of either a centralized plant or smaller
systems should be determined by the users' needs and
resources.
If energy supplies are limited and hand pumps are the only
pumps
available, a system using hand pumps should be considered
rather
than one requiring motor- or engine-driven pumps. The
availability
of trained, qualified persons to operate and maintain the
system properly must also be assessed.
Water systems should be constructed as simply as possible.
Gravity
storage tanks supplied by a single-speed pump are favored
over
variable-speed pumps feeding a water network. Treatment
units,
such as settling basins, can be cleaned manually rather than
with
automatic scrapers and sludge pumping systems. Provision for
disinfecting the water should be made when there is the
possibility
of contamination. Water taps can be centrally located, or
the
water can be piped to each individual home. Transport
distances
must be considered carefully because of costs and other
technical
questions.
A major factor in determining the size of a water system is
the
consumers' ability to pay for the water service. If sufficient
revenues can be generated, the water district can become
self-supporting.
This should be the ideal goal.
USE OF LOCAL RESOURCES
A list should be compiled to see what manufacturers and
suppliers
are available in a given area as a source for pipes,
supplies,
pumps, valves, and replacement parts. Also, an investigation
should be made to see what raw materials might be available.
Such
an investigation should include searches for the right clays
to
make brick, minerals for cement, and sand and rock for
concrete.
Available manpower should be assessed to see who would be
qualified
to work on a water project. An inventory of equipment such
as backhoes, cranes, trenchers, and bulldozers should also
be
made to determine availability.
PUBLIC EDUCATION
An aggressive public education campaign may be necessary to
ensure the acceptance and proper use of a water supply
system by
consumers. If people have never had safe water, they may not
at
first appreciate its value and use it in a manner that will
preserve the system and conserve the water.
Long-term use and maintenance of the system will require the
support of the users. If the users of the system are
involved in
its planning, construction, operation, and maintenance, the
acceptance
and use of the supply will be much greater than in
situations where the system is installed without local
participation.
The involvement of local residents in the development of
four new community water supply systems in Honduras is
described
in the October 1982 and January 1985 issues of VITA News
(see
Bibliography). The success of these water systems is due in
large
part to the efforts of community members.
POSSIBLE PROBLEMS TO CONSIDER
The more complex a system is, the more likely it will have
water
line breaks or maintenance problems. The design phase of a
water
system should contemplate the simplest system possible that
meets
the needs of the community. Acquiring the necessary raw
materials
might also be a major problem. If materials are not readily
available and must be brought in from long distances, the
development
costs will be increased. Sources of safe drinking water
are not always obvious to the community. Locating sources,
such
as underground aquifers, can be time consuming and costly.
In
many parts of the world, a water supply system is totally
foreign
to the residents. Personnel would have to be trained in
constructing,
operating, maintaining, and administering the system.
As stated earlier, the public may also need to be made aware
of
the importance of safe water and of their role in using and
preserving the system.
The potential problems outlined above and any others must be
carefully studied and resolved before development of a water
supply system is started to ensure the success of the
system.
BIBLIOGRAPHY/SUGGESTED READING LIST
American Water Works Association. Recommended Practice for
Distribution
Systems Records.
New York, New York: AWWA, 1940.
Borjesson, E., and Bobeda, C. "New Concept in Water
Service for
Developing
Countries." Journal of the American Water Works
Association.
Vol. 56, No. 7, July 1964.
Cairncross, S., and Feachem, R. Small Water Supplies.
London,
England: Ross
Institute, 1978.
Clark, Viessman, and Hammer. Water Supply and Pollution Control.
2nd edition.
Scranton, Pennsylvania: International Textbook
Company, 1971.
Dallaire, G. "United Nations Launches International
Water Decade;
U.S. Role
Uncertain." Civil Engineering Magazine. Vol. 51,
No. 3, March
1981: 59-62.
McJunkin, F. and Pineo, C. U.S. Agency for International
Development.
Water Supply and
Sanitation in Developing Countries.
Washington,
D.C.: USAID, 1976.
Schiller, E.J., and Droste, R.L., eds. Water Supply and
Sanitation
in Developing
Countries. Ann Arbor, Michigan: Ann Arbor
Science
Publishers, 1982.
Spangler, C. United Nations and World Bank. Low-cost Water
Distribution:
A Field Manual.
Washington, D.C.: World Bank,
December 1980.
Swiss Center for Appropriate Technology (SKAT). Manual for
Rural
Water Supply.
Zurich, Switzerland: SKAT, 1980.
University of Akron, College of Engineering. Engineering
Management
of Water Supply
Systems. Washington, D.C.: United
States Agency
for International Development, 1965.
U.S. Department of Health, Education, and Welfare. U.S.
Public
Health Service.
Individual Water Supply Systems. Washington,
D.C.: HEW, 1950.
U.S. Environmental Protection Agency. Manual of Individual
Water
Supply Systems.
Washington, D.C.: EPA, 1975.
U.S. Peace Corps. Water Purification, Distribution, and
Sewage
Disposal for
Peace Corps Volunteers. Washington, D.C.: Peace
Corps, 1969.
Volunteers in Technical Assistance. "Wind Power for
Roatan Island:
Pumping Water in
Honduras." VITA News, October 1982:
3-7.
Volunteers in Technical Assistance. "Four Island
communities
Inaugurate Water
Systems." VITA News, January 1985: 8-9.
Wagner, E.G., and Lanoix, J.N. Water Supply for Rural Areas
and
Small Communities.
Geneva, Switzerland: World Health Organization.
1959.
SOURCES OF INFORMATION
American Society of Civil Engineers (ASCE)
345 East 47th Street
New York, New York 10017 USA
American Water Works Association (AWWA)
6666 West Quincy Avenue
Denver, Colorado 80235 USA
Environmental Sanitation Information Center
Asian Institute of Technology.
P.O. Box 2754
Bangkok 10501
Thailand
International Reference Centre for
Community Water
Supply and Sanitation (IRC)
P.O. Box 5500
2280 HM Rijswijk
The Netherlands
Pan American Health Organization
525 23rd Street, N.W.
Washington, D.C. 20037 USA
TOOL
Entrepotdok 681/69a
1018 AD Amsterdam
The Netherlands
Water and Sanitation for Health Project (WASH)
1611 N. Kent Street, Room 1002
Arlington, Virginia 22209 USA
World Bank
1818 H Street, N.W.
Washington, D.C. 20433 USA
World Health Organization
20 Avenue Appia
1211 Geneva 27
Switzerland
World Water (monthly magazine)
201 Cotton Exchange
Old Hall Street
Liverpool 3
England
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