A new method of defrosting evaporator coils

A new method is presented to defrost evaporator coils of heat pumps using air as a heat source. At low outdoor temperatures the evaporation temperature can drop below the freezing point of water, the water vapor in the air then freezes on the outer surface of the coil. This increases air side pressu...

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Bibliographic Details
Published in:Applied thermal engineering 2012-06, Vol.39, p.78-85
Main Authors: Mader, G., Thybo, C.
Format: Article
Language:English
Subjects:
Accumulation
Air conditioning. Ventilation
Applied sciences
Coils
Defrost
Devices using thermal energy
Energy
Energy efficiency
Energy. Thermal use of fuels
Evaporation
Exact sciences and technology
Expansion valve
Frost
Heat pump
Heat pumps
Heat transfer
Heating, air conditioning and ventilation
Microchannel heat exchanger
Outdoor
Refrigerants
Techniques, equipment. Control. Metering
Theoretical studies. Data and constants. Metering
Thermal engineering
Valves
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Summary:A new method is presented to defrost evaporator coils of heat pumps using air as a heat source. At low outdoor temperatures the evaporation temperature can drop below the freezing point of water, the water vapor in the air then freezes on the outer surface of the coil. This increases air side pressure drop and reduces the heat transfer capability of the evaporator coil, leading to a decrease in system efficiency. Long frost build-up times would lead to a partly or totally blocked evaporator coil, rendering the system inoperable. To maintain the functionality of the system it is therefore necessary to remove the frost regularly. For a reversible air conditioning system this is typically done by reversing the flow of the system. In the reversed mode the outdoor coil serves as a condenser, hereby melting the frost on the coil surface. Each of these defrost cycles however further reduces the system efficiency substantially. The new method uses an actively distributing valve which is able to feed parallel evaporator passes individually. With this valve single evaporator circuits are regularly shut off. While no refrigerant is evaporated in a closed circuit, the coil surface temperature increases and the flow of the ambient air is sufficient to defrost this part of the evaporator as long as the air temperature is above 0 °C. Experimental results show that under standard frost conditions the evaporator can be kept frost-free and even under severe conditions most of the highly inefficient system reversals can be avoided. Thereby system efficiency is increased significantly. ► Passive defrost of evaporator coils by shutting off individual circuits. ► Refrigerant management with a combined expansion and distribution device. ► Simplified frost and defrost modeling and simulation to demonstrate the method. ► Experimental results for a heat pump with microchannel evaporator.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2012.01.033