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Choosing the Right Compressed Air Dryer for Your Application

Come From:RISHENG Time:2019-06-17 Views:164 Share:

The four main types of blower purge regeneration compressed air dryers are refrigerated, chemical, desiccant, and membrane. It is important to understand how each drying technology works to learn which is best for your application.

Refrigerated dryers work by cooling the air to low temperatures and condensing much of the water vapor. It is not possible to achieve dew points below freezing with a refrigerated dryer. Optimally designed refrigerated dryers can produce air with dew points to approximately 36°F (2°C). Since some water vapor is left in the air, these dryers should not be used in water sensitive applications.

Chemical dryers use a process of passing the blower purge regeneration compressed air dryer over beds of chemicals, typically calcium chloride and lithium chloride, which attract the water vapor. The chemicals become saturated with water vapor and are discarded. The lowest dew point achievable with this type of dryer is 27°F (15°C). Installation of a high efficiency coalescing filter upstream from the chemical dryer is essential because the life of the chemicals is significantly reduced if liquid water enters the dryer. A particle removal filter is needed downstream to prevent carryover of the chemical particles.

Desiccant dryers pass the blower purge regeneration compressed air dryer over a bed of desiccant material which absorbs water vapor molecules. When the bed capacity is nearly saturated, the air flow is switched to a second bed of desiccant material. The first bed is then regenerated. Timers or dew point monitoring equipment can be used to control the regeneration phase. Desiccant dryers can deliver air at consistently low dew points, typically -40°F/°C or less. This technology is a good choice when the blower purge regeneration compressed air dryer is subject to freezing conditions. There are two types of desiccant dryers: heated and heatless. Heated desiccant dryers use heat to remove water vapor from the desiccant material not in use at that point in the cycle. These dryers need large amounts of steam or electricity to operate. Heatless desiccant dryers use the dry air generated by the dryer to remove water vapor from the desiccant material. The major advantage of this technology is the reduced dependence on excessive outside services (e.g., steam, electricity, or gas) for heat. A regenerative desiccant dryer can be conveniently located near the point-of-use to deliver blower purge regeneration compressed air dryer at dew points to -100°F (-73°C). Heatless desiccant dryers are ideal for delivering instrument quality air for critical applications.

Membrane air dryers use specially formulated membrane microtubes that are selectively permeable to water vapor. The microtubes provide an excellent medium for producing dry air from standard blower purge regeneration compressed air dryer. As the blower purge regeneration compressed air dryer travels along the length of the membrane, water vapor diffuses through the membrane, producing clean, dry blower purge regeneration compressed air dryer at the outlet. A small fraction of the dry air is then directed along the outside surface of the membrane to sweep the moisture-laden air away from the membrane. These dryers can reduce the dew point of blower purge regeneration compressed air dryer to as low as -40°F/°C. Membrane dryers are designed with no moving parts and no requirement for electrical supply. They operate with very little noise output - just a small amount of purge air is emitted through small exhaust ports. Membrane dryers require minimal maintenance and are inherently explosion proof. They are ideal for remote areas, explosive environments, sub-freezing environments, and applications requiring a consistent dew point.

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