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If your family gets drinking water from a private
well, do you know if your water is safe to drink? What health
risks could you and your family face? Where can you go for help
or advice? . Approximately 15 percent of North Americans rely on
their own private drinking water supplies. Unlike public
drinking water 
systems serving many people, they do not have experts regularly
checking the water’s source and its quality before it is sent
to the tap. These households must take special precautions to
ensure the protection and maintenance of their drinking water
supplies.
Basic Information
There are three types of private drinking water
wells: dug, driven, and drilled. Proper
well construction and continued maintenance are keys to the
safety of your water supply. Your state water-well contractor
licensing agency, local health department, or local water system
professional can provide information on well construction. The
well should be located so rainwater flows away from it.
Rainwater can pick up harmful bacteria and chemicals on the
land’s surface. If this water pools near your well, it can
seep into it, potentially causing health problems. Water-well
drillers and pump-well installers are listed in your local phone
directory. The contractor should be bonded and insured. Make
certain your ground water contractor is registered or licensed
in your province, if required.
To keep your well safe, you must be sure
possible sources of contamination are not close by. Experts
suggest the following distances as a minimum for protection
— farther is better (see graphic on
the right): 
- Septic Tanks, 50 feet
- Livestock yards, Silos, Septic Leach
Fields, 50 feet
- Patroleum Tanks, Liquid-Tight Manure
Storage and Fertilizer Storage and Handling, 100 feet
- Manure Stacks, 250 feet
Many homeowners tend to forget the value of
good maintenance until problems reach crisis levels. That can
be expensive. It’s better to maintain your well, find
problems early, and correct them to protect your well’s
performance. Keep up-to-date records of well installation and
repairs plus pumping and water tests. Such records can help
spot changes and possible problems with your water system. If
you have problems, ask a local expert to check your well
construction and maintenance records. He or she can see if
your system is okay or needs work.
Protect your own well area. Be careful about
storage and disposal of household and lawn care chemicals and
wastes. Good farmers and gardeners minimize the use of
fertilizers and pesticides. Take steps to reduce erosion and
prevent surface water runoff. Regularly check underground
storage tanks that hold home heating oil, diesel, or gasoline.
Make sure your well is protected from the wastes of livestock,
pets, and wildlife.
Dug Wells
Dug wells are holes in the ground dug by
shovel or backhoe. Historically, a dug well was excavated
below the groundwater table until incoming water exceeded
the digger’s bailing rate. The well was then lined (cased)
with stones, brick, tile, or other material to prevent
collapse. It was covered with a cap of wood, stone, or
concrete. Since it is so difficult to dig beneath the ground
water table, dug wells are not very deep. Typically, they
are only 10 to 30 feet deep. Being so shallow, dug wells
have the highest risk of becoming contaminated.To minimize
the likelihood of contamination, your dug well should have
certain features. These features help to prevent
contaminants from traveling along the 
outside of the casing or through the casing and into the
well.
Dug Well Construction Features
- The well should be cased with a
watertight material (for example, tongue-and-groove
precast concrete) and a cement grout or bentoniteclay
sealant poured along the outside of the casing to the
top of the well.
- The well should be covered by a
concrete curband cap that stands about a foot above the
ground.
- The land surface around the well should
be mounded so that surface water runs away from the well
and is not allowed to pond around the outside of the
wellhead.
- Ideally, the pump for your well should
be inside your home or in a separate pump house, rather
than in a pit next to the well.
Land activities around a dug well can also
contaminate it. While dug wells have been used as a
household water supply source for many years, most are
“relics” of older homes, dug before drilling equipment
was readily available or when drilling was considered too
expensive. If you have a dug well on your property and are
using it for drinking water, check to make sure it is
properly covered and sealed. Another problem relating to the
shallowness of a dug well is that it may go dry during a
drought when the ground water table drops.
Driven Wells
Like dug wells, driven wells pull water
from the water-saturated zone above the bedrock. Driven
wells can be deeper than dug wells. They are typically
30 to 50 feet deep and are usually located in areas with
thick sand and gravel deposits where the ground water
table is within 15 feet of the ground’s surface. In
the proper geologic setting, driven wells can be easy
and relatively inexpensive to install. Although deeper
than dug wells, driven wells are still relatively
shallow and have a moderate-to-high risk of
contamination from nearby land activities.
Driven Well Construction Features
- Assembled lengths of two inches to
three inches diameter metal pipes are driven into the
ground. Ascreened “well point” located at the end
of the pipe helps drive the pipe through the sand and
gravel. The screen allows water to enter the well and
filters out sediment.
- The pump for the well is in one of
two places: on top ofthe well or in the house. An
access pit is usually dug around the well down to the
frost line and a water dis-charge pipe to the house is
joined to the well pipe with a fitting.
- The well and pit are capped with the
same kind of large-diameter concrete tile used for a
dug well. The access pit may be cased with pre-cast
concrete.
To minimize this risk, the well cover
should be a tight-fitting concrete curb and cap with no
cracks and should sit about a foot above the ground. Slope
the ground away from the well so that surface water will
not pond around the well. If there’s a pit above the
well, either to hold the pump or to access the fitting,
you may also be able to pour a grout sealant along the
outside of the well pipe. Protecting the water quality
requires that you maintain proper well construction and
monitor your activities around the well. It is also
important to follow the same land use precautions around
the driven well as described under dug wells.
 Drilled
Wells
Drilled wells penetrate
about 100-400 feet into the bedrock. Where you find
bedrock at the surface, it is commonly called ledge. To
serve as a water supply, a drilled well must intersect
bedrock fractures containing ground water.
Drilled Well
Construction Features
- The casing is usually metal or
plastic pipe, six inches in diameter that extends
into the bedrock to prevent shallow ground water
from entering the well. By law, the casing has to
extend at least 18 feet into the ground, with at
least five feet extending into the bedrock. The
casing should also extend a foot or two above the
ground’s surface. A sealant, such as cement grout
or bentonite clay, should be poured along the
outside of the casing to the top of the well. The
well is capped to prevent surface water from
entering the well.
- Submersible pumps, located near the
bottom of the well, are most commonly used in
drilled wells. Wells with a shallow water table may
feature a jet pump located inside the home. Pumps
require special wiring and electrical service. Well
pumps should be installed and serviced by a
qualified professional registered with your state.
- Most modern drilled wells
incorporate a pitless adapter designed to provide a
sanitary seal at the point where the discharge water
line leaves the well to enter your home. The device
attaches directly to the casing below the frost line
and provides a watertight subsurface connection,
protecting the well from frost and contamination.
- Older drilled wells may lack some
of these sanitary features. The well pipe used was
oftene ight-, 10- or 12- inches in diameter, and
covered with a concrete well cap either at or below
the ground’s surface. This outmoded type of
construction does not provide the same degree of
protection from surface contamination. Also, older
wells may not have a pitless adapter to provide a
seal at the point of discharge from the well.
Hydrofracting A Drilled Well
Hydrofracting is a process that
applies water or air under pressure into your well to
open up existing fractures near your well and can even
create new ones. Often this can increase the yield of
your well. This process can be applied to new wells with
insufficient yield and to improve the quantity of older
wells.
How can I test the quality of
my private drinking water supply?
Consider testing your well
for pesticides, organic chemicals, and heavy metals
before you use it for the first time. Test private
water supplies annually for nitrate and coliform
bacteria to detect contamination problems early. Test
them more frequently if you suspect a problem. Be
aware of activities in your watershed that may affect
the water quality of your well, especially if you live
in an unsewered area. For a list of the most common
drinking water contaminants & MCLs
vist the EPA
website.
Human Health
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The first step to protect
your health and the health of your family is
learning about what may pollute your source of
drinking water. Potential contamination may
occur naturally, or as a result of human
activity.
What are Some Naturally
Occurring Sources of Pollution?
- Microorganisms:
Bacteria, viruses, parasites and other
microorganisms are sometimes found in
water. Shallow wells — those with water
close to ground level — are at most
risk. Runoff, or water flowing over the
land surface, may pick up these pollutants
from wildlife and soils. This is often the
case after flooding. Some of these
organisms can cause a variety of
illnesses. Symptoms include nausea and
diarrhea. These can occur shortly after
drinking contaminated water. The effects
could be short-term yet severe (similar to
food poisoning) or might recur frequently
or develop slowly over a long time.
- Radionuclides:
Radionuclides are radioactive elements
such as uranium and radium. They may be
present in underlying rock and ground
water
- Radon:
Radon is a gas that is a
natural product of the breakdown of
uranium in the soil — can also pose a
threat. Radon is most dangerous when
inhaled and contributes to lung cancer.
Although soil is the primary source, using
household water containing Radon
contributes to elevated indoor Radon
levels. Radon is less dangerous when
consumed in water, but remains a risk to
health.
- Nitrates and
Nitrites: Although high nitrate
levels are usually due to human activities
(see below), they may be found naturally
in ground water. They come from the
breakdown of nitrogen compounds in the
soil. Flowing ground water picks them up
from the soil. Drinking large amounts of
nitrates and nitrites is particularly
threatening to infants (for example, when
mixed in formula).
- Heavy Metals:
Underground rocks and soils may contain
arsenic, cadmium, chromium, lead, and
selenium. However, these contaminants are
not often found in household wells at
dangerous levels from natural sources.
- Fluoride:
Fluoride is helpful in dental health, so
many water systems add small amounts to
drinking water. However, excessive
consumption of naturally occurring
fluoride can damage bone tissue. High
levels of fluoride occur naturally in some
areas. It may discolor teeth, but this is
not a health risk.
What Human
Activities Can Pollute Ground Water?
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Septic
tanks are designed to
have a “leach
field” around them
an area where
wastewater flows out
of the tank. This
wastewater can also
move into the ground
water.
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Bacteria and
Nitrates: These pollutants are
found in human and animal wastes. Septic
tanks can cause bacterial and nitrate
pollution. So can large numbers of farm
animals. Both septic systems and animal
manures must be carefully managed to
prevent pollution. Sanitary landfills and
garbage dumps are also sources. Children
and some adults are at extra risk when
exposed to water-born bacteria. These
include the elderly and people whose
immune systems are weak due to AIDS or
treatments for cancer. Fertilizers can add
to nitrate problems. Nitrates cause a
health threat in very young infants called
“blue baby” syndrome. This condition
disrupts oxygen flow in the blood.
- Concentrated
Animal Feeding Operations (CAFOs):
The number of CAFOs, often called
“factory farms,” is growing. On these
farms thousands of animals are raised in a
small space. The large amounts of animal
wastes/manures from these farms can
threaten water supplies. Strict and
careful manure management is needed to
prevent pathogen and nutrient problems.
Salts from high levels of manures can also
pollute ground water.
- Heavy Metals:
Activities such as mining and construction
can release large amounts of heavy metals
into nearby ground water sources. Some
older fruit orchards may contain high
levels of arsenic, once used as a
pesticide. At high levels, these metals
pose a health risk.
- Fertilizers and
Pesticides: Farmers use
fertilizers and pesticides to promote
growth and reduce insect damage. These
products are also used on golf courses and
suburban lawns and gardens. The chemicals
in these products may end up in ground
water. Such pollution depends on the types
and amounts of chemicals used and how they
are applied. Local environmental
conditions (soil types, seasonal snow and
rainfall) also affect this pollution. Many
fertilizers contain forms of nitrogen that
can break down into harmful nitrates. This
could add to other sources of nitrates
mentioned above. Some underground
agricultural drainage systems collect
fertilizers and pesticides. This polluted
water can pose problems to ground water
and local streams and rivers. In addition,
chemicals used to treat buildings and
homes for termites or other pests may also
pose a threat. Again, the possibility of
problems depends on the amount and kind of
chemicals. The types of soil and the
amount of water moving through the soil
also play a role.
- Industrial
Products and Wastes: Many harmful
chemicals are used widely in local
business and industry. These can become
drinking water pollutants if not well
managed. The most common sources of such
problems are:
- Local
Businesses: These include
nearby factories, industrial plants,
and even small businesses such as gas
stations and dry cleaners. All handle
a variety of hazardous chemicals that
need careful management. Spills and
improper disposal of these chemicals
or of industrial wastes can threaten
ground water supplies.
- Leaking
Underground Tanks & Piping:
Petroleum products, chemicals, and
wastes stored in underground storage
tanks and pipes may end up in the
ground water. Tanks and piping leak if
they are constructed or installed
improperly. Steel tanks and piping
corrode with age. Tanks are often
found on farms. The possibility of
leaking tanks is great on old,
abandoned farm sites. Farm tanks are
exempt from the EPA rules for
petroleum and chemical tanks.
- Landfills and
Waste Dumps: Modern landfills
are designed to contain any leaking
liquids. But floods can carry them
over the barriers. Older dumpsites may
have a wide variety of pollutants that
can seep into ground water.
- Household Wastes:
Improper disposal of many common products
can pollute ground water. These include
cleaning solvents, used motor oil, paints,
and paint thinners. Even soaps and
detergents can harm drinking water. These
are often a problem from faulty septic
tanks and septic leaching fields.
- Lead & Copper:
Household plumbing materials are the most
common source of lead and copper in home
drinking water. Corrosive water may cause
metals in pipes or soldered joints to
leach into your tap water. Your water’s
acidity or alkalinity (often measured as
pH) greatly affects corrosion. Temperature
and mineral content also affect how
corrosive it is. They are often used in
pipes, solder, or plumbing fixtures. Lead
can cause serious damage to the brain,
kidneys, nervous system, and red blood
cells. The age of plumbing materials —
in particular, copper pipes soldered with
lead — is also important. Even in
relatively low amounts these metals can be
harmful. EPA rules under the Safe Drinking
Water Act limit lead in drinking water to
15 parts per billion. Since 1988 the Act
only allows “lead free” pipe, solder,
and flux in drinking water systems. The
law covers both new installations and
repairs of plumbing.
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What
You Can Do...
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Private, individual wells are
the responsibility of the homeowner. To help
protect your well, here are some steps you can
take:
Have your water tested
periodically. It is recommended that water be
tested every year for total coliform bacteria,
nitrates, total dissolved solids, and pH levels.
If you suspect other contaminants, test for
those. Always use a state certified laboratory
that conducts drinking water tests. Since these
can be expensive, spend some time identifying
potential problems.
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Testing more
than once a year may be warranted in
special situations:
- someone
in your household is pregnant or
nursing
- there
are unexplained illnesses in the
family
- your
neighbors find a dangerous
contaminant in their water
- you
note a change in water taste, odor,
color or clarity
- there
is a spill of chemicals or fuels
into or near your well
- when
you replace or repair any part of
your well system
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Identify potential problems as the first step to
safeguarding your drinking water. The best way
to start is to consult a local expert, someone
that knows your area, such as the local health
department, agricultural extension agent, a
nearby public water system, or a geologist at a
local university.
Be aware of your surroundings.
As you drive around your community, take note of
new construction. Check the local newspaper for
articles about new construction in your area.
Check the paper or call your
local planning or zoning commission for
announcements about hearings or zoning appeals
on development or industrial projects that could
possibly affect your water.
Attend these hearings, ask
questions about how your water source is being
protected, and don't be satisfied with general
answers. Make statements like "If you build
this landfill, (just an example) what will you
do to ensure that my water will be
protected." See how quickly they answer and
provide specifics about what plans have been
made to specifically address that issue.
Identify Potential Problem
Sources
To start your search for
potential problems, begin close to home. Do a
survey around your well:
- is there livestock nearby?
- are pesticides being used
on nearby agricultural crops or nurseries?
- do you use lawn fertilizers
near the well?
- is your well
"downstream" from your own or a
neighbor's septic system?
- is your well located near a
road that is frequently salted or sprayed
with de-icers during winter months?
- do you or your neighbors
dispose of household wastes or used motor
oil in the backyard, even in small amounts?
If any of these items apply,
it may be best to have your water tested and
talk to your local public health department or
agricultural extension agent to find way to
change some of the practices which can affect
your private well.
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In addition to the immediate area around
your well, you should be aware of other possible sources
of contamination that may already be part of your
community or may be moving into your area. Attend any
local planning or appeal hearings to find out more about
the construction of facilities that may pollute your
drinking water. Ask to see the environmental impact
statement on the project. See if underground drinking
water sources has been addressed. If not, ask why.
Common Sources of
Potiental Ground Water Contamination
| Category |
Contaminant
Source |
| Agricultural |
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| Commercial |
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Airports
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Jewelry/metal
plating
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Auto repair
shops
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Laundromats
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Boatyards
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Medical
institutions
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Car washes
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Paint shops
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Construction
areas
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Photography
establishments
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Cemeteries
Process waste water drainage
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Dry cleaners
fields/wells
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Gas stations
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Railroad
tracks and yards
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Gulf courses
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Research
laboratories
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Scrap and
junkyards
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Storage tanks
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| Industrial |
- Asphalt plants
- Petroleum
production/storage
- Chemical
manufacture/storage
- Pipelines
- Electronic
manufacture
- Process waste
water drainage
- Electroplaters
fields/wells
- Foundries/metal
fabricators
- Septage
lagoons and sludge
- Machine/metalworking
shops
- Storage tanks
- Mining and
mine drainage
- Toxic and
hazardous spills
- Wood
preserving facilities
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| Residential |
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Fuel Oil
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Septic
systems, cesspools
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Furniture
stripping/refinishing
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Sewer lines
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Household
hazardous products
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Swimming pools
(chemicals)
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Household
lawns
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| Other |
- Hazardous
waste landfills
- Recycling/reduction
facilities
- Municipal
incinerators
- Road deicing
operations
- Municipal
landfills
- Road
maintenance depots
- Municipal
sewer lines
- Storm water
drains/basins/wells
- Open burning
sites
- Transfer
stations
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For more information see A Guide To Well Water
Treatment And Maintenance from Health
Canada.
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