A brief discussion of the operating vapor-compression cycle is helpful to indicate other potential refrigeration problems in real systems. In the basic cycle, slightly subcooled refrigerant leaves the condenser at high pressure and flows into the liquid receiver if one is present. The refrigerant then enters the throttling device (capillary tube, TXV, etc.) where the pressure is dropped. It then enters the evaporator as a two-phase mixture (liquid and vapor) and evaporates or boils at low temperature, adsorbing heat. Slightly superheated refrigerant vapor exits the evaporator and enters the suction line accumulator, if one is present (used to trap any transient liquid slugs). The refrigerant vapor then enters the compressor where the pressure and temperature are increased as the compressor compresses the refrigerant vapor. The vapor leaving the compressor is superheated, and the compressor discharge is the hottest point in the cycle. This refrigerant is cooled and condensed in the condenser where heat is rejected, and the refrigerant is condensed to liquid. Refrigerant actually leaves the condenser slightly subcooled (subcooled liquid) to assure condensation has been complete. Any non-condensable vapors in the system will be unable to condense in the condenser and will appear as gas bubbles in the condensed liquid stream. These non-condensables may collect in the condenser and displace refrigerant from the condenser heat exchanger, thereby reducing the effective surface area of the condenser.
The compressor changes the low pressure vapor to high pressure vapor sending it threw the condenser to cool and turn it back into liquid.
The air conditioning pump, or more accurately the compressor.
The compressor changes the low pressure gas into a high pressure gas which then has the heat of compression removed in the condensor to turn it into a high pressure liquid.
as heat is removed from the refrigerant at the condenser it reach it saturated temperature n then it'll start to flash change state to a high pressure liquid
LBMDOLPH-CHECKMATE on soundcloud
metering device
By a combination of refrigeration and pressure.
21.1" vacuum
No, it will not condense if its partial pressure does not exceed its (maximum) partial pressure of the component's liquid (or solution) at the same(!) temperature.
aneroid barometer
Metamorphic rock
Metering device
The compressor changes the low pressure gas into a high pressure gas which then has the heat of compression removed in the condensor to turn it into a high pressure liquid.
as heat is removed from the refrigerant at the condenser it reach it saturated temperature n then it'll start to flash change state to a high pressure liquid LBMDOLPH-CHECKMATE on soundcloud
The metering device. Depending on what type of system you have, this will either be a Fixed Orifice Tube or it will be a Thermal Expansion Valve.
By a combination of refrigeration and pressure.
The King valve is closed, starving the low pressure side, creating more vacuum while charging with a liquid
As the atmospheric pressure changes, the force pushing on the surface of the liquid changes. Therefore,the height of the liquid in the tube increases as the atmospheric pressure increases.
compressor
Cooling and/or pressure changes gases to liquids.
Metering divice
Variation of pressure and temperature..that changes. Gas into liquid..temp should be decreased likewise pressure..
21.1" vacuum