This information is relevant for emergency water storage in containers of 55 gallons or less. If you are storing water in a container larger than 55 gallons or have an auxiliary water tank, please consult the following disinfection calculator and guidance.
The Department of Environmental Quality, Division of Drinking Water recommends water storage of 1 gallon per person per day for 2 weeks. This is based on 2 quarts or ½ gallon per person per day for drinking water and food preparation, and another 2 quarts or ½ gallon per person per day for other limited uses such as hand washing, teeth brushing and dishwashing. (This is a total of 14 gallons per person for 2 weeks.)
A normally active person needs to drink at least 2 quarts (1/2 gallon) of water each day. Hot environments and intense physical activity can double that amount. Children, nursing mothers and people suffering from disease or injury may need more water. Immunocompromised people may want to take extra precautions to minimize their risk in an emergency.
Water should be stored in containers manufactured for food use. Never use a container that has held toxic substances.
Plastic bleach bottles and gallon milk containers are generally manufactured with non-durable plastic that promotes biodegradability and is undesirable for long term water storage. Water stored in non-durable plastic containers may become toxic over time from breakdown products from the plastic container walls.
The disposable, plastic milk bottle is thin-walled and tends to develop leaks easily. Liquid chlorine bleach bottles are made of thicker polyethylene plastic and may be used for water storage if the empty bottles are thoroughly rinsed with hot water and allowed to dry. However, the use of bleach bottles for water storage is not recommended, because of the potential danger of accidentally drinking bleach instead of water. If bleach bottles are used for water storage, remove the bleach label and write “WATER” indelibly across the bottle. Children may mistakenly associate the size and color of bleach bottles with acceptable sources for drinking water and mistakenly drink bleach. As such, bottles must be positively identified, and bleach must be kept out of the reach of children.
If plastic containers are used, care should be taken to assure that they are made of plastic approved for food contact by the Federal Food and Drug Administration (FDA). Polyethylene plastic is approved for food contact and is commonly used for containers of various sizes, including large 55 gallon drums. Certain types of plastic containers are not intended for food contact (such as vinyl plastic waterbeds or trash containers) and may leach undesirable chemicals into stored water. Leaching from approved plastics into water is negligible.
Stored water must be clean water. Use the best quality available for water storage. Water must be from a system with a Division of Drinking Water “Approved” rating. Water stored in thoroughly clean plastic or glass containers can be chemically disinfected for long-term storage by treating each gallon with 4 to 5 drops of unscented liquid chlorine bleach (Clorox or Purex type bleaches, containing 4% to 6% sodium hypochlorite). One teaspoon of bleach disinfects 5 gallons of water. Allow 20 to 30 minutes before drinking. This level of treatment will prevent growth of microorganisms during storage. Most municipal water storage facilities are already disinfected so no additional treatment is necessary. Fill a clean food grade container with tap water and screw on lids.
Store water containers away from cleaning supplies, fertilizers and other products with strong odors. These odors could be absorbed by the storage containers and transferred to the water.
Water stored in plastic containers should be filled to the top so there is no air space and should be stored in a cool, dry location away from petroleum and insecticide products, and away from strong odor food or perfumed products.
Vapors from these substances could permeate the plastic and affect the water. Thick walled polyethylene containers are significantly less permeable to vapors than are thin-walled containers.
Once the container is opened, use the water rather than putting it back into storage. If stored water has a flat taste, pour it back and forth between two containers several times. Rotate water every 1 to 2 years.
Store as much water as possible, more than the bare minimum (especially in desert and hot climates). Be certain to label each container so there will be no questions about its contents. Include the date and information on the method of disinfection used.
If a disaster catches you without a stored supply of clean water, you can use the water in your house piping system, your hot water heater and even ice cubes. Know the location of your house’s water shut off valve. In a disaster in which your water company’s supply of water to your house has been interrupted (e.g., broken water mains in the streets), shut off water supply into your house to prevent backflow of contaminated water. To use the water in your piping, let air into the plumbing by turning on the faucet in your house at the highest level. A small amount of water will trickle out. Then, leaving the highest faucet on, obtain water from the lowest faucet in the house.
To use water in your hot water heater, first turn off the electricity or gas supply, and then close off the cold water supply line to the water heater. Open the drain at the bottom of the tank and start the water flowing by turning on a hot water faucet somewhere else in the house. Collect the water containers and disinfect each gallon with 4 – 5 drops of liquid bleach. Allow 20 to 30 minutes before drinking. (Note: If the water is cloudy and/or from an unsafe origin, 16 drops of liquid chlorine bleach is recommended.) You can use water in the tank of your toilet (not the bowl). Disinfect as with water from the water heater.
Some water sources may have chemical contamination that makes them unacceptable for drinking. For example, waterbed mattresses usually contain organic chemicals in the wall plastic and biocidal chemicals in the water to prevent algal, fungal and bacterial growth. These chemicals can make the water unsafe to drink. During an emergency such water may be used for hand washing and laundering.
Some emergencies may warrant obtaining water from sources outside the home. The hazards of using water, including ice and snow, of unknown quality needs to be carefully weighed against the obvious life-sustaining need for drinking water. Even crystal clear, mountain stream water can be contaminated with disease-causing parasites such as giardia. Sterilization or disinfection can reduce the microbiological hazard of water of unknown quality, but there is no safe method for reducing the chemical hazard (e.g., toxic chemicals and radioactive materials) of water of unknown quality. If water is cloudy, chemical disinfection must be supplemented by some kind of filtration or heat sterilization (20 to 30 minutes of boiling) to assure complete destruction of disease-causing organisms. (Note: If water is cloudy and/or from an unsafe origin, 16 drops of chlorine bleach is recommended.)
In addition to having a bad odor and taste, contaminated water can contain microorganisms that cause diseases such as dysentery, typhoid and hepatitis. You should disinfect all water of uncertain purity before using it for drinking, food preparation or hygiene.
There are many ways to disinfect drinking water. None of the listed methods are perfect. The methods described below will kill most microbes, but they will remove very few chemical contaminants. Before water is disinfected, let any suspended particles settle to the bottom of the container, or strain the water through layers of paper towels, filters such as coffee, clean cheesecloth, or clean cloth into a clean container.
Better clarification can be obtained by drawing cloudy water through a “capillary siphon”.
A capillary siphon can be constructed by rolling a small, clean, terry cloth towel into a long roll. Place one end of the roll into a container of cloudy water. Drape the rest of the roll over the edge of the container so that it hangs free from the container’s sidewall. Be sure the free hanging (dry) end of the towel extends below the water level by several inches. Place a clean container below the free hanging end. Soon water from the upper container will wet the whole towel as the capillary action draws water through the towel to the lower container. With cloudiness removed, chemical disinfection can be more effective in destroying disease-causing organisms.
Boiling is the safest method of disinfecting water. It is preferred over any method of chemical disinfection because most disease-causing microorganisms cannot survive the heat of the sterilizing boil. Water must be heated to boiling and held in a vigorous rolling boil for 5 minutes minimum (preferably 10 to 20 minutes). Let the water cool before drinking. Boiled water will taste better if you put oxygen back into it by pouring the water back and forth between two clean containers. This will also improve the taste of stored water.
Chemical disinfection of water is an acceptable alternative to heat sterilizing, but only if the water is clear. Disease-causing organisms, such as viruses, can “hide” inside the microscopic dirt particles that cause cloudiness in water. They can thereby escape the action of the disinfecting chemical and remain capable of producing disease.
Chemical disinfection is less reliable than disinfection via boiling for several reasons. For example, the more organic matter there is in the water, the more chemicals are required. The colder the water is, the longer the “contact time” (the length of time between addition of disinfecting chemicals to the water and use of the water) should be. Additional factors affecting the success of disinfection include the amount and type of chemicals used, water pH (how acidic or basic the water is), and types of disease-causing organisms in the water.
You can use household liquid bleach to kill microorganisms. Use only regular household liquid bleach that contains 5.25% sodium hypochlorite. Do not use scented bleaches, color safe bleaches or bleaches with added cleaners. Each gallon of water should be treated with 4 – 5 drops of liquid chlorine bleach or 16 drops of liquid chlorine bleach if the water is cloudy. This is just under ¼ of a teaspoon per gallon. One teaspoon of bleach disinfects 5 gallons of water. Treated water should be thoroughly mixed and allowed to stand for 30 minutes before using. A slight chlorine odor should be detectable in the water. If it is not, repeat the dosage and let it stand another 15 minutes before using. Treated water may have a slight chlorine taste, but this is additional evidence of safety.
Since liquid chlorine bleach loses strength over time, only fresh bleach should be used for water disinfection. For bleach that is 1 to 2 years old, the dosage should be doubled. Bleach older than two years should not be used unless absolutely necessary because of uncertainty as to how much the active ingredients have deteriorated.
Iodine tablets have the advantage of being more effective against amoebic dysentery cysts and certain other intestinal parasite cysts than chlorine-based disinfectants such as sodium hypochlorite or Halazone tablets. Sporting good stores commonly carry iodine tables. Be certain iodine tablets are fresh, since they lose effectiveness with age. Fresh tablets have a gray color. They have a shelf life of approximately 3–5 years unopened. The label should show an EPA registration number. Often iodine tablet containers carry labels recommending restrictions on use by pregnant or lactating women. Check the label before purchasing the tablets. Follow instructions on the label, mixing thoroughly and allowing adequate “contact time”. The iodine tablet should impart a light yellow to tan color to the water and a slight odor.
Halazone tablets (4 dichlorosulfamyl benzoic acid) for emergency water disinfection are commonly carried by pharmacies and drug stores. The label should show an EPA registration number. Be certain to note the expiration date since the shelf life is only about 2 years. According to the manufacturer: “It is important that the containers are tightly closed to prevent the absorption of moisture from the air. If decomposition of the tablets should occur, they take on a yellowish appearance, have a strong objectionable odor, and of course, should not be used”.
Chemical disinfection, liquid bleach, iodine tablets, and Halazone tablets will not remove cryptosporidium.
Temporary water storage tanks for non-potable water are helpful in various industrial operations such as fracking, agriculture, and collection of stormwater runoff. Aboveground water storage tanks are made of carbon steel, stainless steel, or fiberglass. You can also use durable poly tanks made of high-density cross-linked polyethylene.
The table below shows a general idea of the number of barrels, the equivalent tank capacity in gallons, and the tank dimensions. For unique capacity requirements, contact us or request a quote.
Barrels Gallons Diameter x Height 1,000 41,000 21′-0″ x 16′-0″ 5,000 210,000 30′-0″ x 40′-0″ 14,000 580,000 50′-0″ x 40′-0″ 20,100 840,000 60′-0″ x 40′-0″ 151,000 6,350,000 150′-0″ x 48′-0″Table: general idea of the number of barrels, the equivalent tank capacity in gallons
The Specific Gravity Weight (SPG) is the ratio of the density of the substance to the density of the reference liquid. The higher the SPG, the more weight the tank can hold. Aboveground water storage tanks should have an SPG of 1.Specific Gravity Weight
For aboveground water storage, use a dark-colored tank to prevent sunlight from penetrating the body. If sunlight penetrates the polyethylene body, it can aid the growth of algae and bacteria, which are usually harmless but can affect the color and taste of water.
Corrugated steel tanks are the most durable during changes in weather, followed by polyethylene and fiberglass tanks. This is also what makes steel tanks the most expensive out of the three.
Also known as “pillow tanks,” bladder tanks are collapsible and are made of durable fabric or rubber, and can be quickly deployed for temporary water storage.
Ideal for short-term, non-potable water storage for industrial wastewater, water purification, and pollution control. You can install them in emergency situations on rough terrain.
These are massive, shop-built reservoirs that can hold thousands of gallons of water. They are robust, leak-free, and provide adequate water pressure if placed on high ground.
These tanks stand vertically above the ground and are perfect for temporary water storage in refineries, water treatment plants, chemical and manufacturing facilities, construction sites, and environmental facilities. They could be made of plastic, polyethylene, fiberglass, or steel.
These portable water storage tanks lie horizontally on the ground and may or may not require a foundation. Horizontal tanks are available in polyethylene, with high-visibility railings, guard rail assembly on the roof, and a steel casing to house the tank.
All aboveground Storage Tanks (ASTs), including those that store non-potable water, must meet regulations under the 40 CFR 112 of the US EPA. The EPA classifies them as bulk storage containers.
Bulk storage containers are regulated under diverse federal acts and requirements enforced by state and local government authorities. But there is no uniform national federal program by the government that regulates aboveground water storage tanks.
For example, aboveground tanks in Minnesota are subject to the MCPA’s rules for designing and operating ASTs, which also covers piping, valves, containment areas, pumping system, and loading areas. Check with local authorities for state or county government guidelines. You can review Minnesota’s administrative rules and definitions here.
Industrial and residential areas use aboveground water storage tanks for consumption, domestic (non-potable), and industrial applications.
In areas where groundwater level is low or the quality is poor, people use aboveground water storage tanks. You can use non-potable water for emergencies such as fire suppression where you can feed this water into the sprinklers of fire protection systems.
Heavy rainwater runoff can cause soil erosion damaging the plants and harming the wildlife. You can divert the rainwater flow from rooftops to aboveground storage tanks and use it for irrigation. You can run the collected rainwater through a purification system and make it potable.
Graywater is not fit for drinking, as it is produced as a result of other domestic or industrial operations such as stormwater runoff, domestic wastewater, roof runoff, and HVAC condensation.
Instead of using scarce freshwater, use non-potable water to irrigate the fields. Storing water on a farm in aboveground storage tanks can give you year-round supply of water even in the dry months. You can also use this water to feed cattle or control fire outbreaks. It also allows for more judicious use of water because it prevents flooding.
Non-potable water stored in aboveground storage tanks can help meet the sustainability needs of entire facilities.
For instance, Stanford University uses non-potable water to irrigate its golf course, agricultural leasehold, athletic fields, and campus landscaping. This helps save almost one million gallons of potable water a day. Stanford uses this water for consumption in domestic, research and academic applications, and is beneficial for the environment.
Building water storage tanks above ground is cheaper because you don’t have to dig and build reinforcements that are necessary for underground tanks.
Because the tank is fully visible, you can immediately troubleshoot and make repairs. It takes less time and effort and makes the process less costly.
You can alter the external appearance of an aboveground water storage tank to make it blend with or even enhance its surroundings. Aboveground tanks can serve other purposes as well. For example, a business may want to display them as part of its sustainability practices.
Yes, all aboveground tanks, irrespective of their contents, should meet regulations under the 40 CFR 112 of the US EPA, which classifies them as bulk storage containers.
You can use a variety of containment measures, including:
You can place vertical poly tanks directly on level ground or inside a temporary plastic berm. Larger tanks that hold more than 2,000-gallons such as our 21,000 gallon steel tanks should have a prepared stable, level base capable of supporting 200,000 lbs or more of combined weight of the tank and contents. You can also use other materials such as tightly packed sand, pea gravel, or equipment mats.
The base should provide uniform support in cold and hot climates, frost, thaw, erosion, snow, and other environmental disturbances.
Regular inspection of ASTs is important to prevent any damage or leaks. One must keep the following parameters in mind: