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Using Ultraviolet Light and Filtration
To allow water treatment professionals to provide another value added service to their clients and to help facilities improve efficiency and lower costs, here is some basic information regarding cooling tower and re- circulation loop water treatment. This article will focus on integrating UV disinfection and filtration into existing systems to help reduce chemicals and improve system performance.
About Cooling Towers
Cooling towers and recirculation loops are considered heat rejection systems. They move heat to the atmosphere through the cooling of water to a lower temperature. Some common applications for cooling towers are air-conditioning systems, water-cooling of equipment and general manufacturing needs.
The type of heat rejection in a cooling tower is defined as “evaporative” in that it allows a small portion of the water being cooled to evaporate into a moving air stream to provide significant cooling to the rest of that water stream.
As this happens, the cooling towers become efficient air cleaners (scrubbers). This process allows airborne contaminants and particles to become deposited into the cooling water. This, combined with the contaminants in the feed water, creates an environment for microorganism growth, solid deposits and scaling.
Microorganisms tend to thrive in the re-circulated water and on wet surfaces. Bacteria, slime and algae foul heat– exchanger surfaces and in some cases attack and destroy system components.
Some common cooling tower water problems include:
In order to combat the biological growth problems, facility operators generally use chemicals (biocides)
to stop bio-growth.
While the use of chemicals helps control the overall biological problems, this solution does have some downsides such as:
Ultraviolet (UV) light, which is a proven technology for drinking water, can be applied to the treatment of cooling tower water. As with drinking water, cooling tower water enters the UV system where it is exposed to high doses of UV light. The UV lamps produce light in the 254 nm wavelength. At this wavelength, UV light targets the microorganism’ DNA. Exposure to the light scrambles the DNA and prevents the microorganisms from reproducing.
Some common benefits of UV light
cooling tower water treatment are:
In order to make the addition of UV a reality, the cooling tower water treatment will also need to include a filtration system. The use of basic filters (40 to 50 micron) will help remove the solids from the water. This will make the UV more effective and prevent solids from settling elsewhere in the cooling loop.
This has a two-fold impact. The first is that it will prevent the UV system from becoming fouled and the second is that
it will lower the maintenance on the actual cooling equipment (condensers and exchangers).
Integration and Sizing
Depending on size and desired results of the facility, the UV system can be designed to handle the full flow or a side stream. In order to correctly size the system, the following needs to be determined:
Generally, a 10-percent side-stream system is designed. This assumes that the water will be turned over every four to five hours. Since the water will be re-circulated, it will have multiple passes in front of the UV on a given day. The integration of the UV/filtration will significantly reduce the amount of biocides required.<
The system should be comprised
of the following:
The above can be installed in the loop
and results can be seen immediately.
By integrating a combination UV disinfection and mechanical filtration system, the facility can significantly reduce the amount of chemicals required (a small amount of chemicals is required to prevent growth on the sides of the piping as well as in the equipment) and the costs associated with purchasing and storing them.
In addition, this will create a safer
work environment and allow the facility
to operate as a “green” company.