Water is in the air, so it’s in your compressed air. Depending on the temperature & humidity there will be either a lot or a little water, but there will always be water.
When air is compressed the level of water and humidity increases. Why? Because you need 8 cubic feet of air to generate one cubic feet of compressed air. Increasing the pressure also means increasing the level of water saturation.
In order to obtain dry compressed air we need to trap the water (stages 1 & 2) and remove moisture from the compressed air (stages 3 & 4).
STAGE 1: The Tank.
Water removal is done is stages. The first stage of water separation is the tank. When compressed air comes out of the pump it is hot (~180°F) that means any water in the air is water vapor. The tank is room temperature so when that hot water vapor makes contact with the inside of the relatively cool tank, it condenses on the inside of the tank. Drain the tank daily or install an Automatic Timer Drain.
STAGE 2: Air / Water Separator.
The next stage of water separation should be a mechanical Air / Water Separator - looks like an in-line air filter. What it does is directs the incoming air in a spiral and uses centrifugal force to separate out the water in the compressed air. Depending on the temperature of the air, this process should remove 99% of the water in the compressed air. At this point the air may be dry enough for your operation.
Note: Install Point-of-use Filters & Dryers , Air Tool Dryer or a SUPER-DRY at each station to catch the last remnants of water and dirt in the air lines before it reaches your tools and applications. Refer to page 3 for point-of-use solutions.
STAGE 3: Refrigerated Air Dryer.
The next stage is to cool the air coming from the compressor. Why cool the air? Because cold air can't hold water. The colder the air the less water it holds. That is why the industry talks about the dew point. Dew point is the temperature at which the humidity condenses into water droplets. A refrigerated air dryer cools the air down to 38°F. It is basically a refrigerated coil mated with the air line. This removes the heat from the air line and cools the air in it. The water is diverted by gravity and removed with an Automatic Timer Drain. A Compressed Air Filter should be placed before the air dryer to protect it.
STAGE 4: Desiccant Air Dryer.
This stage of air drying takes the dew point down to -40°C using a SUPER-DRY desiccant air dryer. This is very dry and is needed for painting, printing, and instruments. The beads physically absorb the water in the compressed air, so the air must be relatively dry before entering or the beads will become loaded up with moisture very quickly and stop working. There is a Moisture Indicator on the front of this unit giving you the percentage of relative humidity, when it reaches 80% the desiccant needs to be changed (typically once a year. When excessive oil is contained in the compressed air (ex: old compressor) a Compressed Air Filter is required up-stream of the SUPER-DRY desiccant air dryer. Why? Because if the beads are contaminated with oil they will not absord water (umbrella effect).
It is also possible to dry the air directly at the point-of-use (ex: paint booth, dust collector, sand blast cabinet, etc.). In this case we need to dry the air in two stages: the separation of the water using an Air / Water Separator, followed by a SUPER-DRY desiccant air dryer.
AIR TOOLS PROTECTION
An Air Tool Dryer will deliver dry compressed air to your tools and reduce air tools maintenance due to rusting of the components. It should be installed up-stream of the FRL. Will prevent freezing of nail guns in a cold environment.
Compressed air has applications in virtually all industries. Its uses range from being an efficient, reliable source of pneumatic power in manufacturing plants to operating critical instrumentation in process industries. In every application, air quality can be adversely affected by contaminants like water, oil and dirt. The result is lower productivity, increased maintenance, and higher operating costs. For these reasons, air system designers must recognize and understand the types of contaminants they face.
The most prevalent contaminant is water. Water, in the form of vapour, enters the air system at the compressor intake, and is concentrated to the saturation point by compression. As cooling occurs downstream of the compressor, the moisture in this saturated air condenses into harmful liquid water.
Still another contaminant, oil, is injected into air systems by lubricated compressors. Many gallons of oil can enter an air system over the course of a year in this way.
Dirt takes many forms in air systems since it enters from several different sources. Small particles of atmospheric dust not removed by intake filters are concentrated by compression. Pipe scale forms over time by the gradual rusting process. Hot-running, lubricated compressors create fine particles of carbon dust when lubricants break down.
Today's air system designer is faced with the challenge of improving air quality through the selection of drying and filtering equipment that is best suited to removing these contaminants. Judgments must be made based on the particular application, the degree of dryness and cleanliness required, and the types of equipment available. That's where we can help. Super-Dry offers complete, cost-effective, practical solutions to your drying and filtering needs. We have the expertise necessary to assist you in the selection of the optimum combination of equipment for your application.
Marc A. Rayle is in the compressed air and filtration industry since 2002. He graduated from Concordia University with BA in Commerce. Based in Laval, Quebec, Canada Marc is Super-Dry Systems Inc. President. His pastimes include working out, golfing, and close-up magic.