heat pump: see air conditioning air conditioning, mechanical process for controlling the humidity, temperature, cleanliness, and circulation of air in buildings and rooms. Indoor air is conditioned and regulated to maintain the temperature-humidity ratio that is most comfortable and healthful.
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heat pump

Device for transferring heat from a substance or space at one temperature to another at a higher temperature. It consists of a compressor, a condenser, a throttle or expansion valve, an evaporator, and a working fluid (refrigerant). The compressor delivers vapourized refrigerant to the condenser in the space to be heated. There, cooler air condenses the refrigerant and becomes heated during the process. The liquid refrigerant then enters the throttle valve and expands, coming out as a liquid-vapour mixture at a lower temperature and pressure. It then enters the evaporator, where the liquid is evaporated by contact with the warmer space. The vapour then passes to the compressor and the cycle is repeated. A heat pump is a reversible system and is commonly used both to heat and to cool buildings. It operates on the same thermodynamic principles as refrigeration.

heat pump [′hēt ‚pəmp]

(mechanical engineering)

A device which transfers heat from a cooler reservoir to a hotter one, expending mechanical energy in the process, especially when the main purpose is to heat the hot reservoir rather than refrigerate the cold one.

Heat pump

The thermodynamic counterpart of the heat engine. A heat pump raises the temperature level of heat by means of work input. In its usual form a compressor takes refrigerant vapor from a low-pressure, low-temperature evaporator and delivers it at high pressure and temperature to a condenser (see illustration). The pump cycle is identical with the customary vapor-compression refrigeration system. See Refrigeration cycle

This dual purpose is accomplished, in effect, by placing the low-temperature evaporator in the conditioned space during the summer and the high-temperature condenser in the same space during the winter. Thus, if 70°F (21°C) is to be maintained in the conditioned space regardless of the season, this would be the theoretical temperature of the evaporating coil in summer and of the condensing coil in winter. The actual temperatures on the refrigerant side of these coils would need to be below 70°F in summer and above 70°F in winter to permit the necessary transfer of heat through the coil surfaces. If the average outside temperatures are 100°F (38°C) in summer and 40°F (40°C) in winter, the heat pump serves to raise or lower the temperature 30° (17°C) and to deliver the heat or cold as required.

The heat pump is also used for a wide assortment of industrial and process applications such as low-temperature heating, evaporation, concentration, and distillation.

heat pump

heat pump

A device that transfers heat from a cooler reservoir to a hotter reservoir by means of a heat exchanger, requiring the expenditure of mechanical energy in the process; used in an air conditioner whose cooling cycle can be reversed so that it can function as a heater.

Heat Pump

a device that transfers thermal energy from a lowtemperature heat source, most often the environment, to a high-temperature heat receiver. The operation of a heat pump requires the consumption of external mechanical, electrical, chemical, or other type of energy. The processes that occur in a heat pump are similar to those involving the working fluid of a refrigerator, except that refrigeration equipment is designed to generate cold, whereas a heat pump generates heat. Liquids with a low boiling point, such as Freon or ammonia, are the working fluids normally used in a heat pump.

The heat flowing into the receiver of a heat pump consists not only of a quantity equivalent to the external work performed but also heat from a heat source, such as river water. Consequently, the energy conversion factor for a heat pump is always greater than 1, and the conversion process is more favorable than the direct conversion of electrical, mechanical, or chemical energy into heat. However, the trend in power engineering toward joint production of heat and electric power limits the use of heat pumps to situations in which other forms of thermal energy cannot be readily supplied—for example, in locations far from district heat and power plants.

Heat pumps are sometimes used for heating buildings in regions with warm climates, since the same unit may be using during the summer to cool incoming air. Because of fuel shortages, heat pumps were widely used during World War II (1939–45), particularly in countries that had a surplus of cheap hydroelectric power, such as Switzerland, Sweden, and Norway.

V. S. BUNIN

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No references found			Since a geothermal heat pump runs on electricity measured in kilowatt hours (kWh), and a condensing boiler is fueled by natural gas measured in therms, it's necessary to convert kWh of electricity into "therms" to make an accurate comparison. Condensing Boiler Vs Geothermal Heat Pump - Cheap Heat Surprise by Sam Streubel / Environmental issues community An air source heat pump extracts heat from the outside air in the same way that a fridge extracts heat from it's inside. Guide to best products by The Journal (Newcastle, England) KNH chief executive Simon Rogers said yesterday: "To our knowledge, this is the biggest single ground source heat pump project undertaken. Digging deep to provide green energy for homes; Work begins on new ... by Huddersfield Daily Examiner (Huddersfield, England)			heat of compression heat of condensation heat of cooling heat of crystallization heat of decomposition heat of dilution heat of dissociation heat of emission heat of evaporation Heat of Formation Heat of Fusion heat of hydration heat of ionization heat of linkage heat of mixing Heat of Reaction heat of solidification heat of solution heat of sublimation heat of transformation Heat of Transition Heat of Vaporization heat of wetting Heat Pipe heat prostration Heat Pump heat quantity Heat Radiation heat rash heat rate heat reactor heat recovery Heat Regime of Soil heat release Heat Resistance Heat Resistance and Thermal Stability of Polymers heat run heat seal heat set Heat Setting heat shield heat shock protein heat shock response heat shunt heat sink heat slug heat source heat sterilization heat storage heat stress index Heat Supply			Heat of Vaporation heat of vaporisation heat of vaporization heat of vaporization heat of vaporization Heat of vapourisation heat of wetting Heat Oil Fire Resistant Heat pad Heat paste Heat pipe Heat pipe Heat Pipe Experiment Heat Pipe Experiment Package Heat Pipe Heat Exchanger Heat Pipe Performance Heat Pipe Radiator Assembly Heat Pipe Technology Heat Pipe Transient Analysis Model Heat pipes Heat plant Heat plant Heat power plant Heat power plant Heat Power Station Heat producers heat prostration heat prostration heat prostration heat prostration Heat Pump Heat pump and refrigeration cycle Heat Pump Centre Heat Pump Clothes Dryer Heat Pump Pool Heaters Heat Pump Programme Heat Pump Unit Heat Pump Water Heater Heat Pumping Heat Pumping Heat pumps Heat pumps heat quantity Heat radiation Heat radiation Heat radiation Heat radiator Heat radiator Heat radiator heat rash heat rash heat rash heat rash Heat Rate Heat Rate Heat Rate Improvement of Power Plants heat ray Heat rays heat reactor Heat recovery Heat Recovery Boiler