In a conventional refrigeration system theoretically the heat of compression is the energy required for compression.
When compressed gasses are expanded then energy is released and its temperature drops.
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Einstein's refrigeration system uses Ammonia vapour to drive and...
In an adiabatic situation is the heat required to liberate all the ammonia vapour from a given mass of water, exactly the same as the energy gain when the same mass of vapour is re-absorbed, in other words is more energy needed to brake the bondage?
Is the vapour given off during the generation cycle of an absorption refrigeration system basically pure Ammonia and does the Ammonia conform to the the saturation/pressure charts on the high temperature side and low temperature side of these systems?
