Refrigeration cycle


Refrigeration cycle


Mechanical refrigeration cycle is accomplished by continuously circulating, evaporating, and condensing a fixed supply of refrigerant /gas in a closed system.

Refrigeration system

Evaporation occurs at a low temperature and low pressure while condensation occurs at a high temperature and high pressure. Thus, it is possible to transfer heat from an area of low temperature to an area of high temperature.

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beginning the cycle at the evaporator inlet , the low-pressure liquid expands, absorbs heat, and evaporates, changing to a low-pressure gas at the evaporator outlet.

The compressor , pumps this gas from the evaporator through the accumulator , increases its pressure, and discharges the high-pressure gas to the condenser .

The accumulator is designed to protect the compressor by preventing slugs of liquid refrigerant from passing directly into the compressor.

An accumulator should be included on all systems subjected to varying load conditions or frequent compressor cycling. In the condenser, heat is removed from the gas, which then condenses and becomes a high-pressure liquid. In some systems, this high-pressure liquid drains from the condenser into a liquid storage or receiver tank .

On other systems, both the receiver and the liquid line valve  are omitted.

A heat exchanger between the liquid line and the suction line is also an optional item, which may or may not be included in a given system design.

Between the condenser and the evaporator an expansion device is located.
Immediately preceding this device is a liquid line drier , which prevents plugging of the valve or tube by retaining scale, dirt, and moisture.

The flow of refrigerant into the evaporator is controlled by the pressure differential across the expansion valve or, in the case of a thermal expansion valve, by the degree of superheat of the suction refrigerant. Thus, the thermal expansion valve shown requires a sensor bulb located at the evaporator outlet.

In any case, the flow of refrigerant into the evaporator normally increases as the evaporator load increases.

As the high pressure liquid refrigerant enters the evaporator, it is subjected to a much lower pressure due to the suction of the compressor and the pressure drop across the expansion device.

Thus, the refrigerant tends to expand and evaporate. In order to evaporate, the liquid must absorb heat from the air passing over the evaporator.

Eventually, the desired air temperature is reached and the thermostat or cold control  will break the electrical circuit to the compressor motor and stop the compressor.
As the temperature of the air through the evaporator rises, the thermostat or cold control remakes the electrical circuit.

The compressor starts, and the cycle continues.
In addition to the accumulator, a compressor crankcase heater is included on many systems. This heater prevents accumulation of refrigerant in the compressor crankcase during the non-operating periods and prevents liquid slugging or oil pump out on startup.
Additional protection to the compressor and system is afforded by a high and low pressure cutout .

This control is set to stop the compressor in the event that the system pressures rise above or fall below the design operating pressure range.

Other controls not indicated on the basic cycle which may be part of a system include evaporator, pressure regulators, hot gas bypass regulators, solenoid valves, suction pressure regulators, condenser pressure regulators, low-side or high-side float refrigerant controllers, oil separators and others.

It is extremely important to analyze completely every system and understand the intended function of each component before attempting to determine the cause of a malfunction or failure.

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