Hydrogen
sulfide gas is a nuisance that is not usually a health risk
at concentrations present in household water. Water containing
hydrogen sulfide, commonly called sulfur water, has a distinctive
"rotten egg" odor, which may be especially noticeable when running
hot water. Such water can discolor coffee, tea and other beverages,
and alter the appearance and taste of cooked foods.
Hydrogen
sulfide dissolved in water can also corrode plumbing metals,
such as iron, steel, copper and brass and exposed metal parts
in washing machines and other water-using appliances. The
corrosion of iron and steel from hydrogen sulfide forms ferrous
sulfide or "black water" which can darken silverware and discolor
copper and brass utensils. Hydrogen sulfide can also interfere
with the effectiveness of water softeners.
A concentration
as low as 0.1 milligrams hydrogen sulfide per liter of water
(mg/l ) is detectable by smell by most people. However, characteristic
hydrogen sulfide taste can be detected in water with a hydrogen
sulfide concentration as low as 0.05 mg/1.
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Hydrogen
sulfide gas is formed from decomposing underground deposits
of organic matter, such as decaying plant material. This gas
occurs in deep or shallow wells and can also enter surface water
through springs. Hydrogen sulfide from sewage pollution can
occur in some surface water, in poorly constructed wells or
in shallow wells close to sewer lines or septic systems. Wells
drilled in shale or sandstone, or near coal or oil fields often
have hydrogen sulfide present in the water.
The
presence of hydrogen sulfide may be seasonal and frequently
occurs in well water which also contains appreciable levels
of iron and/or manganese, or that has a low pH.
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To determine
an appropriate treatment method, it is necessary to find out
how much hydrogen sulfide is present in the water supply. Since
hydrogen sulfide is a gas that is dissolved in water and can
readily escape from it, determining the concentration of hydrogen
sulfide requires that the water sample be tested at the site
or be immediately stabilized for laboratory analysis. Sample
bottles with stabilizing chemical should be obtained from the
laboratory that does the analysis. These stabilized water samples
cannot be analyzed for other contaminants. When sewage pollution
is a suspected source of hydrogen sulfide, the water should
be tested for coliform bacteria
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The recommended
treatment for reducing hydrogen sulfide varies with its concentration
in household water. Select the treatment appropriate for the
amount of hydrogen sulfide present in the water supply from
the following treatment options: (Where ranges for hydrogen
sulfide concentrations given below overlap one another, more
than one treatment method may be suitable.)
-
Trace amounts of hydrogen sulfide (up to a few tenths mg/1)
At this level, activated carbon filtration will reduce the
unpleasant taste associated with hydrogen sulfide but has
a very limited capacity for odor absorption. Hydrogen sulfide
gas is adsorbed onto the carbon surface. In this method,
the filter, when exhausted, must be replaced, not recharged.
-
Less than 2 mg/1 hydrogen sulfide
Aeration (adding air to the water) is an appropriate treatment
method. In any aeration system, the water must be protected
from bacterial contamination and freezing, and there are
large space requirements. Another limitation of this method
is that the aeration process produces a strong hydrogen
sulfide odor near the aerator which may be unpleasant if
near the household living area Furthermore, this process,
by itself, may not always reduce the hydrogen sulfide to
non-detectable levels. However, the addition of a carbon
filter may remove some of the remaining trace amounts of
hydrogen sulfide.
-
1-10 mg/1 hydrogen sulfide
The use of an iron-removal filter containing manganese green sand
is suggested. Manganese green sand filters must be recharged
with a solution of potassium permanganate when the oxygen
is depleted. This process is similar to regenerating a water
softener and usually must be implemented at intervals from
one to four weeks depending on the condition of the water,
size of the unit, and amount of water consumption. Water
with a pH below 6.7 may need to be treated with an acid
water neutralizer before iron removal filtration will be
effective.
-
More than 6 mg/1 hydrogen sulfide
Constant chlorination using an automatic chemical feed pump
is the most common treatment method. The recommended dosage
is 2 mg/1 chlorine for 1 mg/1 hydrogen sulfide. The chlorine
should be added ahead of the mixing tank and sufficient
storage must be provided to maintain 20 minutes of contact
time between the water and the chemical. This process may
produce objectionable taste in the water. Depending upon
the amount of chlorine added, an activated carbon filter
may be used to obtain chlorine-free water for cooking and
drinking. The same carbon filter can also reduce any remaining
hydrogen sulfide. Maintenance and replacement of filter
systems should be considered since sulfur, iron, manganese
and other suspended materials in the water can quickly clog
the filter.
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is possible
to have the characteristic "rotten egg" odor in water even when
laboratory tests show the absence of hydrogen sulfide. In this
case, the odor is caused by harmless bacteria that chemically
change sulfate in the water to hydrogen sulfide. These bacteria
live on the hot water side of the home water distribution system.
Shock
chlorination of the entire water system, including storage,
hot water tanks, and distribution lines, kills the bacteria.
This process introduces very high concentrations of chlorine
into the water system. Chlorine should remain in the system
for several hours, preferably overnight. If the situation
persists, continuous chlorination may be required.
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Hydrogen
sulfide in drinking water is a common nuisance contaminant.
Although it is not hazardous to health, the offensive odor and
corrosivity of household water containing hydrogen sulfide make
treatment desirable. Although there are various treatment alternatives,
chlorination is the most commonly used and effective. Often,
the treatment for hydrogen sulfide is the same as for iron and
manganese, allowing removal of all three contaminants in one
process.
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Publication #: 356-488
For more
information about reducing hydrogen sulfide in household water,
contact your local Virginia Cooperative Extension office.
The
authors wish to thank the following individuals who reviewed
this publication:
Kathleen Parrott, Extension Specialist, Housing, Virginia
Tech
Kathryn Sevebeck, Educational Director, Virginia Water
Resources Research Center, Blacksburg.
Disclaimer and Reproduction Information: Information in
NASD does not represent NIOSH policy. Information included in
NASD appears by permission of the author and/or copyright holder.
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