Refrigerant


Refrigerants are working fluids that carry heat from a cold environment to a warm environment while circulating between them. For example, the refrigerant in an air conditioner carries heat from a cool indoor environment to a hotter outdoor environment. Similarly, the refrigerant in a kitchen refrigerator carries heat from the inside the refrigerator out to the surrounding room. A wide range of fluids are used as refrigerants, with the specific choice depending on the temperature range needed and constraints related to the system involved.
Refrigerants are the basis of vapor compression refrigeration systems. The refrigerant is circulated in a loop between the cold and warm environments. In the low-temperature environment, the refrigerant absorbs heat at low pressure, causing it to evaporate. The gaseous refrigerant then enters a compressor, which raises its pressure and temperature. The pressurized refrigerant circulates through the warm environment, where it releases heat and condenses to liquid form. The high-pressure liquid is then depressurized and returned to the cold environment as a liquid-vapor mixture.

Refrigerants are also used in heat pumps, which work like refrigeration systems. In the winter, a heat pump absorbs heat from the cold outdoor environment and releases it into the warm indoor environment. In summer, the direction of heat transfer is reversed.
Refrigerants include naturally occurring fluids, such as ammonia, carbon dioxide, propane, or isobutane, and synthetic fluids, such as chlorofluorocarbons, hydrochlorofluorocarbons, or hydrofluorocarbons. Many older synthetic refrigerants have been banned to protect the Earth's ozone layer or to limit climate change. Some refrigerants are flammable or toxic, making careful handling and disposal essential.
Refrigerants, while strongly associated with vapor compression systems, are used for many other purposes. These applications include propelling aerosols, polymer foam production, chemical feedstocks, fire suppression, and solvents.
Chillers are refrigeration systems that have a secondary loop which circulates a refrigerating liquid, with vapor compression refrigeration used to chill the secondary liquid. Absorption refrigeration systems operate by absorbing a gas, such as ammonia, into a liquid, such as water.

Requirements and desirable properties

The selection of a refrigerant for a given purpose depends on a combination of factors. Different refrigerants, having different properties, are better suited to some applications than others.

Thermophysical property requirements

In thermodynamic terms, refrigerants transport thermal energy, which is called enthalpy. Enthalpy greatly increases or decreases during evaporation or condensation. The difference between the enthalpy of the vapor and liquid phase is called the latent heat of vaporization. The latent heat of vaporization allows substantial energy to be absorbed or released, with minimal temperature change, in the evaporator or condenser. Engineers control the temperatures in the evaporator and condenser by changing the fluid's pressure.
A refrigerant must achieve a boiling point below the desired temperature of the cold environment. Heat will then flow from the cold environment into the refrigerant, causing it to evaporate. The boiling point is lower if the refrigerant pressure is lower. For this reason, the refrigerant in the evaporator will have a reduced pressure. The evaporator pressure should be above atmospheric pressure to prevent air from leaking into it.
Similarly, the refrigerant must achieve a boiling point above the temperature of the warm environment, so that heat will flow out of the refrigerant as it condenses. Since boiling point rises with increasing pressure, the refrigerant in the condenser will have an elevated pressure.
For most refrigeration systems, a critical point temperature well above the condenser temperature is desirable. When the critical point temperature is above the condenser temperature, the refrigerant can condense from the vapor to the liquid phase at nearly constant temperature; but if the critical point were below the condenser temperature, no phase change could occur. For fixed evaporator and condenser temperatures, increasing the critical point temperature farther above the condenser temperature raises the energy efficiency of a refrigeration cycle.
However, as the critical point temperature rises, the vapor density at the compressor inlet decreases. A lower density raises the volumetric flow rate of vapor needed for a given amount of cooling. Thus, a trade-off between energy efficiency and volumetric efficiency underlies the selection of a refrigerant.
The refrigerant vapor's specific heat capacity also strongly affects performance. A lower specific heat capacity avoids liquid formation in the compressor, but too low a heat capacity can result in undesirably hot vapor at the compressor outlet. Optimization tends to favor refrigerant molecules with fewer atoms. A high latent heat of vaporization and a triple point temperature well below the evaporator temperature are also desirable.
A few refrigerants, like carbon dioxide, may operate in warm environments that are above the critical point temperature. In these transcritical refrigeration cycles, the condenser must be replaced by a gas cooler operating over a wider temperature range.
Refrigerants are sometimes blended to achieve a balance of desired properties. Pure refrigerants vaporize at a constant temperature when pressure is held constant. In contrast, blended refrigerants vaporize across a small range of temperature. This phenomenon is called temperature glide.
For safety, an ideal refrigerant should be non-toxic and non-flammable. For environmental protection, the refrigerant should have no ozone depletion potential, and a very low global warming potential. Refrigerants that are not naturally present in the atmosphere should have a short atmospheric lifetime and should decay into environmentally benign by-products.

Other requirements

The refrigerant must be chemically stable during use.
Refrigerants should be non-corrosive to the components in the system. To protect the compressor, the refrigerant should be miscible in the lubricant, and shaft seals compatible with the refrigerant must be available. For hermetically sealed systems, the refrigerant vapor may have contact with the motor windings, and so it should have a high dielectric strength.
For safety, an ideal refrigerant should be non-toxic and non-flammable. For environmental protection, the refrigerant should have no ozone depletion potential, and a very low global warming potential. Refrigerants that are not naturally present in the atmosphere should have a short atmospheric lifetime and should decay into environmentally benign by-products.
The refrigerant should have a low cost. Legal regulations can also be a strong factor in the selection of refrigerants.
The selection of a refrigerant for a specific purpose involves trade-offs among the all factors mentioned. Often, no refrigerant is entirely ideal, and several different refrigerants will appear as reasonable options.

History

Vapor compression refrigeration was first described theoretically by Oliver Evans in 1805, using diethyl ether as the refrigerant. In 1834, Jacob Perkins patented a vapor compression system, also describing diethyl ether as the refrigerant. The first working prototype of that system was built by John Hague the same year, but used a rubber distillate, caoutchoucine, as the refrigerant. In the 1850s, James Harrison, working in Australia, developed a Perkins-type system also using diethyl ether. Ice making and meat packing were early applications of his technology.
Many more inventions followed during the second half of the 19th century. In the 1860s, Thaddeus Lowe developed a carbon dioxide system. The 1870s saw the introduction of systems based on ammonia, sulfur dioxide, dimethyl ether, and methyl chloride. Several 19th century refrigerants continue in use to this day, but others have been discarded for safety or performance reasons. By start of the 20th century, ammonia was predominant in industrial systems.
Household use of vapor compression refrigerators and air conditioners emerged in the early 20th century, as small electric motors became available to drive the vapor compressor. These early systems used ammonia, isobutane, methyl chloride, propane, and sulfur dioxide. Each of these had drawbacks for household use, such as odor, toxicity, or flammability.

The development of halogenated refrigerants (CFCs and HCHCs)

In the 1920s, Thomas Midgley Jr., working with Albert Henne and Robert MacNeary, made a systematic study of synthetic refrigerants, seeking a fluid that was non-toxic, non-flammable, and stable. Midgley's team focused in on chlorinated and fluorinated hydrocarbons. By 1931, dichlorodifluoromethane came to market. R-12 was soon followed by trichlorofluoromethane in 1932, and chlorodifluoromethane in 1936. R-11 and R-12 are chlorofluorocarbons, or CFCs, and R-22 is a hydrochlorofluorocarbons, or HCFC. The trade name Freon was used for R-12, which at that time was also called F-12.
The R- numbering system for refrigerants was developed by DuPont in the years that followed. The letter R is followed by a number that uniquely identifies the chemical structure of the refrigerant. The system has since become an international standard. Often, a more specific group of letters is used in place of R to denote the chemical family of the refrigerant. For example, R-12 may be called CFC-12 to indicate that it is a chlorofluorocarbon.
CFC and HCFC refrigerants were immensely successful, and they dominated the market for half a century. By 1987, R-12 was used in essentially all refrigerators and R-22 in nearly all air conditioners. Automotive systems relied on R-12, water chillers using centrifugal compressors favored R-11, and low-temperature commercial refrigeration used a blended refrigerant, R-502.