96-14E                                               November 1996

Preventing Frozen Water Pipes

Many cold climate communities struggle each winter to prevent water supply pipes from freezing. Northern communities have explored various prevention techniques and technologies. This Information Bulletin suggests a number of techniques that may help to prevent pipes from freezing and reduce water waste.

Design Factors

A community should consider several factors when exploring ways to prevent pipes from freezing. These include pipe design, pipe depth, expected water and ground temperatures, and accessibility of pipes in winter for thawing and repairing.

Depth

The depth at which to bury the piping is a major consideration during installation of a community's water supply system. System designers must ensure all factors, including the type of soil and its insulating properties, are considered prior to installation. Areas of permafrost will have unique considerations.

Insulate Pipes

Insulating pipes will reduce the amount of heat lost from the water. The service connection should be insulated right into the heated portion of the house or house trailer; otherwise freezing can still occur. Although expensive, factory insulated pipes reduce on-site labour and ensure that no breaks occur in the insulation during installation.

Continuous Circulation

Some water supply systems involve laying various configurations of pipe which allow continuous water flow. A commonly used layout consists of a single pipe that loops back to its origin. The water flows through the pipe, including through the service connections to each house. Unused water continues to move through the pipe, and is returned to the water plant. To ensure the water being distributed remains above freezing, a boiler is often used to heat the water to about 4_C.

Double Piping

In the past, some communities have installed a double pipe configuration, but it has been an expensive option, both in terms of installation and maintenance. Two pipes are laid beside one another. The larger is the supply pipe; the smaller returns water to the origin for heating and recirculation.

Both the single and double pipe configurations avoid water waste. However, heating the water uses considerable energy.

Bleeding

Bleeding means the controlled wasting of water through orifices to maintain water flow in the main lines, service lines, and sewers to prevent freezing of the pipes. Originally, communities installed carefully sized orifices in the dead end of single line supply systems. The water then flowed continuously through this hole, usually to the sewer pipe. This resulted in water being wasted throughout the year. Although it may seem like an inexpensive option, it results in the ongoing costs of treatment of large volumes of water that flow directly into the sewer system. These large volumes of water can dilute wastewater to a point where treatment is ineffective. This method can also result in cross-contamination between potable water and wastewater.

To reduce water wasted from bleeders, two options to regulate bleeders have been developed:

Timers

The first, "Timers", turn bleeders on and off automatically. Timers are set to clear water from the pipe before the water reaches ice-forming temperatures. If the electricity is interrupted, or the timer is turned off, the bleeder should remain open. Timers should be set to the worst case scenario (assume coldest possible temperatures) unless the timers can be adjusted from above ground. In addition, if the timers can be adjusted from above ground, the bleeders can be closed during the summer. The capital cost is relatively low, but the system still wastes large volumes of water.

Temperature Sensors

The second, "Temperature Sensors", waste the least amount of water of all bleeder methods, but is also the most expensive and difficult to install and maintain. Sensors are installed in the coldest sections of the supply pipes. Therefore, locations must be examined, and trials must be performed to verify the most appropriate positioning of sensors. When the sensor reads below a preset temperature (usually just above freezing), the sensor triggers the opening of the bleeder. The bleeder closes when the sensor reads above another preset temperature. If electricity is interrupted, the system automatically allows a continuous water flow, which will last until the electricity is reinstated.

In many Northern homes, a tap is left running during cold months to prevent pipes from freezing. This practice wastes water. Therefore, orifice plates can be installed on a special tap, and a lesser amount of water (less than 0.5 gpm) can be wasted from within the home. A shut-off valve can be installed to conserve water during warmer months.

Heat Tracing

Another technology that can help prevent water pipes from freezing is heat tracing. A long element heats the pipe and water to prevent freezing; and can also be used to thaw frozen pipes. There are three methods of heat tracing:

Glycol Heat Tracing System

Glycol heat-tracing systems transfer heat by using a series of pipes in a closed loop circulation system. The system consists of boilers to supply heat, a heat exchanger from a main heat reservoir, circulating pump(s), an expansion tank, specialty valves, and controls. The output heat exchanger is the heat trace tubing that runs in a loop next to the pipe requiring heat. While the total system efficiency of a boiler-fired glycol heat-tracing loop is greater than that for electric resistance heat tapes, their maintenance requirements (including heated space for the boilers, pumps, etc.) are often considered their main disadvantage. Cross contamination is a risk. In addition, because of the increased pump capacity requirements, installation costs, and loop leaking potential, glycol heat-tracing along a length greater than 600 to 900 metres is rare.

Heat Tape

The second heat tracing method requires placement of a heat tape (a wire imbedded in a rubber type compound) alongside the supply pipe. If some sections of pipe are especially susceptible to freezing, the heat tape may be applied to only those areas of the pipe. There are several disadvantages of this method including: the system will not function if power is interrupted, thermostat malfunctions can result in overheating or under-heating in the system; or wires inside the tape can short circuit or break without detection, allowing the water to freeze. For safety and fire-prevention reasons, ground fault interrupters should be used with all heat tape installations. Ordinarily, the heat tape does not last as long as the pipe. The vulnerable areas may have to be excavated more frequently to replace the tape. This is expensive and inconvenient. Even with surface monitoring, the pipes would still have to be excavated on an emergency basis.
Please note: Every fall, carefully inspect any heat tape before using. As with any electrical cord, connections or insulation can erode creating a potential hazard.

In-Line Heat Tracing

The third method of heat tracing is called "In-Line Heat Tracing". Several communities in northern Manitoba have used this method; one northern community has successfully used this method for the last ten years. A 5/8 inch copper pipe (refrigerant copper pipe) is placed in the water supply pipe. Inside the pipe is an electrical heat tape which can run to a maximum of 180 metres (600 feet). If the tape fails, it can be replaced without digging up the entire length of affected pipe. Access to the heat tape is through the connection point between the water supply line and the copper pipe. If the electricity is interrupted, the heat tape can thaw any ice that forms. The copper pipe is flexible, so it does not break when frost heaves occur. The Canadian Standards Association has recently approved heat tape without the copper pipe container for use inside water supply pipes This should result in an approximate 50% decrease in cost for the in-line system.

Water Heating

Some communities heat water in boilers to about 4 degrees C before distribution through the supply system. This method is used in conjunction with other systems, especially when challenging freezing problems occur. This system works well in some areas, but the energy and maintenance costs can be considerable.

Pump-back Reservoir Systems

Reservoir systems consist of a tank with a pump attached. The tank and pump are located inside the house and are connected between the municipality's pipe supplying the water and the house's supply pipe. The tank gradually fills; if the household does not use the water, it is pumped back into the municipal supply pipe. The system uses household heat to increase the water temperature so the water will not freeze when pumped back into the supply pipe. This system wastes no water, but each unit is quite expensive.

However, the householder must maintain the unit. If the householder unplugs the pump, or there is a power failure, the tank will drain, and water will flow to the drain at a preset rate. The result is a continuous bleeder for the duration of the power interruption. One way to ensure that the units are maintained and are not unplugged is to install water meters, and to charge for water use by the unit.

There are industrial versions of this technology, which may be more effective in saving water overall. Because of the cost, industry has only installed them if there was a serious commitment to water conservation.

Utilidor

An expensive but effective way to solve all these challenges is for the community to build a utilidor. This heated tunnel can house all utilities (electrical, gas and water), thereby making them easily accessible for installation and maintenance. If sufficient in size, it can also be used as a pedestrian passageway between buildings.

Conclusion

All of these freezing prevention strategies have strong and weak points. They will reduce the incidence of frozen pipes during our cold winters. However, all methods described may still leave supply pipes susceptible to freezing. Therefore, provisions should ALWAYS be made so that a frozen pipe can be thawed as easily and economically as possible. A cost/benefit analysis may be useful to help determine which technique or set of techniques will provide the most favourable investment for a particular community.

The occurrence of frozen water supply pipes can be reduced substantially while also reducing water and energy waste. Improving efficiency of water use can decrease costs of water and wastewater handling, and assist in protecting the environment.

Inquiries on Manitoba's Water Use Efficiency Program may be directed to the Water Use Efficiency Coordinator at:

Pollution Prevention Branch
Manitoba Environment
123 Main Street
Suite 160
Winnipeg MB R3C 1A5
Telephone: (204) 945-8980
Toll Free: 1-800-282-8069, ext. 8980