UV Disinfection 101

Ultraviolet disinfection is a means of killing or rendering harmless,microorganisms in a dedicated environment. These microorganisms can range from bacteria and virusesto algae and protozoa. UV disinfection is used in air and water purification, sewage treatment, protection of food and beverages, and other disinfection and sterilization applications. A major advantage of UV treatment is that it is capable of disinfecting water faster than chlorine without cumbersome retention tanks and harmful chemicals. The focus of this article will be on water treatment.

Selecting the Proper Application
for Ultraviolet DisinfectionIt is very important to know the quality of
the water you are working with and also to define your desired results. UV is an option when there is a concern about the microbiological integrity of the water. The best feature of UV is that it kills microorganisms without adding or subtracting from the water chemistry. On the other hand, UV does not leave any measurable residual in the water; therefore it is recommended that it be installed as the final step of treatment and located as close as possible to the final distribution system. Once the quality of your water source has been determined, you will need to look for things that will inhibit the UV from functioning properly, such as iron, manganese, TDS, turbidity and suspended solids. Some of you may be thinking that this too much preparation for a UV system. Let me ask you, as a water treatment professional, would you leave your customer's home without addressing these issues anyway?

Iron and Manganese both are capable of precipitating on the quartz sleeve and preventing the UV energy from transmitting into the water. Iron should not exceed 1.0 ppm. At that level additional maintenance is required to keep the quartz sleeve clean and transparent. It is recommended that both iron and manganese are removed from the water, or at least reduced to levels that eliminate thepossibility of staining.

Total Dissolved Solids (TDS) should not exceed 500 ppm, however due to many factors, this number is nebulous at best. There are many factors that make up this equation, such as the distance between the lamp and the wall of the UV chamber; the particular make-up of the dissolved solids and how fast they absorb the available UV energy; flow rate; output of the lamp; etc. Calcium, in high amounts, has a tendency to build up on the quartz sleeve, again impeding the UV energy from penetrating the water. Contact your supplier for details on the amount of TDS your equipment is capable of handling. The solution could be as simple as running your system slower for a higher dosage.

Turbidity is the inability for light to travel though water. Turbidity makes water cloudy and aesthetically unpleasant. In the case of UV, levels over 1 NTU can shield microorganisms from the UV energy making the process ineffective.

Suspended Solids need to be reduced to a maximum of 5 microns in size. Larger solids have the potential of harboring or encompassing the microorganisms and preventing the necessary UV exposure. Pre-filtration is a must on all UV applications.

General Installations
Once the aforementioned problems have been solved, and you are convinced that the water quality has been established to promote UV disinfection, you should find a location to mount the system that offers easy access for service. You will need to have access to the prefilter, to the UV chamber for annual lamp changes (provided you're using a hard glass lamp), and regular maintenance on the quartz sleeve. The quality of the water will determine the maintenance time schedule of the quartz sleeve. You will want to locate an electrical outlet. Note: Using a UV system and a pump on the same electrical line may cause problems with and shorten the life of the UV lamp and ballast.

Types of UV Lamps
UV lamps are constructed from two types of quartz glass: a soft glass and a hard glass. Both are used in the disinfection of water, however the usable life of each type of glass varies. Soft glass lamps have a usable life of 2,000 hours and are found in small noncritical devices such as fish aquariums, air purification and small countertop systems. Hard glass lamps have a usable life of 9,000 hours and are found in higher flow and higher output applications.

The difference between the two types of lamps is the quality of the glass used in their construction. A germicidal lamp is constructed of quartz glass, argon gas, mercury and the filaments used to ignite the mixture. When a lamp is lit and has achieved its ideal operating temperature of 104 degrees F, the mercury changes from its solid state into a gaseous state. While the lamp is in this operating state it imparts particles into the pores of the glass. This process is referred to as solarization. Solarization takes place in the hard glass lamp in about 9,000 hours, due to its smooth and less porous surface (that's four-and-a-half times longer than a soft glass lamp). UV lamps may burn for many years, however the solarization of the lamp will determine the UV energy output.

Dosage is the most critical function of UV disinfection. It is thecombination of the lamp intensity and the dwell time that makes up dosage. The equations is: Intensity X Exposure = Dosage. This is important to know when sizing equipment. Each manufacturer uses a different standard for sizing their equipment, but it comes down to this equation. For example, if your manufacturer values their equipment, with a flow rate of 10 gpm, at a dosage of 16,000 microwatt second per squared centimeter, and you are working with an application that requires 32,000 mws/cm2, you would simply cut the flow rate in half to achieve the new UV dosage.Dosage is another reason to consider the difference between the higher output of a hard glass lamp verses a soft glass lamp.

The purpose of the quartz sleeve is to help the lamp to maintain its ideal operating temperature. It is also to isolate the lamp from the water. For the maximum UV transmission of energy, the quartz sleeve needs to be constructed of the same high-quality materials as the lamp. The quartz sleeve should be wiped down every three to six months which is contingent upon the quality of the water you are dealing with. It is recommended that every UV application is inspected after three month's time. This will give you an opportunity to monitor the effect the water chemistry is having on the quartz sleeve, and your maintenance schedule time frame can be modified from there. The sleeve should be wiped down with a soapy solution each time it is inspected. If there is a residue left you may need to use a non-abrasive cleaner that is formulated to remove iron and scale buildup. Abrasive cleaner could scratch the sleeve and make it unusable.

Applications for UV Disinfection
Applications include well applications; point-of-entry; point-of-use; post mix; vending machines; pharmaceuticals; cooling towers; boats and RVs; pre- and post-reverse osmosis; fish hatcheries; aquiculture; bottled water; cabins; laboratories; hospitals; spas; boiler feed water; water softeners; and others.


About the author

This article was written by Edwin L. Roberts, director of sales and marketing of Hydrotech Inc., Valencia, California, 661-294-8888.<