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Water:
From Its Source to Our Taps
Water
is a vital element in each of our lives. Not only is it essential
to our health, but we also use it for numerous household tasks.
Every day we use water for cooking, bathing, and cleaning, and
drinking; but how often do we think about its source? Where
does our water come from? How is it treated? How do we know it
is safe to drink? To
answer these questions, it's important to go back to the basics.
There are two main sources of water: surface water and groundwater.
Surface Water is found in lakes, rivers, and reservoirs.
Groundwater lies under the surface of the land, where it
travels through and fills openings in the rocks. The rocks that
store and transmit groundwater are called aquifers. Groundwater
must be pumped from an aquifer to the earth's surface for use.
Consumers
receive their water from one of two sources: a private well, or
a community water system. A household well pumps groundwater for
household use. The source of a community water system may be either
surface water or groundwater.
Private
Household Wells
Approximately
15 percent of the U.S. population relies on individually owned
and operated sources of drinking water, such as wells, cisterns,
and springs. The majority of household wells are found in rural
areas. Those
who receive their water from a private well are solely responsible
for the safety of the water. Private wells are not subject to
federal regulations, and are generally regulated on a very limited
basis by states. Local health departments may assist well owners
with periodic testing for bacteria or nitrates, but the bulk of
the responsibility for caring for the well falls on the well owner.
Since the well owner is primarily
responsible for the water, it is important to know what poses
a threat to the well and the groundwater which is its source.
A variety of sources can cause well water to become contaminated.
Several contaminants occur in nature
that may present a health risk if they are found in drinking water.
They include bacteria, viruses, uranium, radium, arsenic, and
fluoride. Many of these contaminants are naturally present in
rock formations, and consequently end up in the water supply.
Other sources of contamination are
a result of human activity such as manufacturing or agriculture,
or individual misuse. The following activities may cause harmful
chemicals to enter the well water owner's water supply.
-
Leakage
from waste disposal, treatment, or storage sites.
-
Discharges
from factories, industrial sites, or sewage treatment facilities.
-
Leaching
from aerial or land application of pesticides and fertilizers
on yards or fields.
-
Accidental
chemical spills.
-
Leakage
from underground storage tanks.
-
Improper
disposal of household wastes such as cleaning fluids, paint,
and motor oil.
Well
owners generally disinfect or otherwise treat the water from their
wells to remove the contaminants that are caused by such activities.
Community
Water Systems
Approximately
85 percent of the U.S. population receives its water from community
water systems. Community water systems are required to meet the
standards set by the U.S. Environmental Protection Agency (EPA)
under the authority of the Safe Drinking Water Act (SDWA). The
SDWA was passed by Congress in 1974 to establish nationally consistent
drinking water standards. A standard is the maximum level of a
substance that the EPA has deemed acceptable in drinking water. In
1986 the SDWA was amended to require the EPA to publish standards
for 83 specific contaminants, and additional standards thereafter.
To date, the EPA has issued or proposed limits for 87 substances.
Community water systems are currently revising their drinking
water programs to meet the more stringent requirements of the
amendments. Community
water systems must ensure that the drinking water they supply
does not have contaminant levels higher than the standards of
the SDWA, the SDWA amendments, or state regulations. In
order to set a standard for a drinking water contaminant, the
EPA first reviews the data concerning the health effects the substance
may cause. The EPA then proposes non mandatory Maximum Contaminant
Level Goals (MCLG's). MCLG's are set at zero for contaminants
that are known or probable human carcinogens. For non carcinogens,
MCLG's are set at a level where no adverse health effects would
occur with a margin of safety. At
the same time, the EPA also proposes a Maximum Contaminant
Level (MCL), the enforceable drinking water standard, which
is set as close to the MCLG as possible, taking into account technological
and economic considerations. After
a time for public comment and review of the MCL and MCLG, the
EPA enacts a final regulation. States are expected to adopt the
standard within 18 months of enactment. The
SDWA requires utilities to conduct routine monitoring and testing
of public water supplies. Two types of sampling are required.
Routine Sampling takes place on a regular basis and ensures
that a treatment plant is running properly for delivering a consistent
quality of drinking water. It also determines whether water quality
meets the MCL's. When
a routine sample analysis indicates elevated levels of a particular
contaminant that may exceed EPA or state standards, states may
require systems to take a check sample. Check samples are
used to confirm the results of a problem discovered during routine
sampling. The
EPA generally delegates to the states the authority to enforce
all federal drinking water standards, but can intercede when necessary.
Sates must set standards that are no less stringent than the EPA's.
Point
of Use Technologies
Whether
consumers receive their water from a household well or a community
water system, they may wish to treat it at its point-of-use (POU).
Even water supplied by a community water system, which meets EPA
standards, can generally benefit from POU treatment. Consumers
have the option to choose the higher quality of water that POU
technologies can provide. POU
technologies treat water at single or multiple taps or for the
whole house, and improve water quality in a variety of ways. Unusual
taste, color, and odor or water may be corrected by POU technologies,
and some POU devices also reduce harmful contaminants.
One of the most popular POU technologies
is water softening. An important characteristic of water is hardness,
which is measured in grains per gallon (gpg). The more grains
per gallon, the harder the water. The U.S. Geologic Survey reports
that hard water is found in more than 85 percent of the United
States. Hard water has many disadvantages. It can clog pipes and
appliances, reduce clothing longevity by 15 percent, leave a soapy
film on bathtubs and shower tiles, and increase water heating
costs by nearly 30 percent while shortening the life of the heater.
A water softener reduces the hardness of water, eliminating these
problems and resulting in substantial savings.
Besides
softening, a variety of POU equipment is available for improving
drinking water and other special purposes. Each technology is
designed to solve one or several different water quality problems.
In order to choose the right equipment, it is important to confirm
the nature and extent of the problem. The
first step in correcting a water quality problem is often to have
the water tested. When the safety of the water is in question,
it should always be tested by a state-certified or other reputable
laboratory. Testing for aesthetic concerns such as taste, odor,
color, and hardness may be performed in the home by a professional
water treatment dealer. Testing
the water will help determine the proper treatment necessary.
Before purchasing a product, become an educated consumer. Determine
which contaminants the product reduces, and to what level. Also
check the product's performance capabilities, maintenance provisions,
and warranty.
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