Abstract: A compression-type refrigeration system is disclosed, in which "flash gas" formation is eliminated without artificially maintaining condenser temperature and pressure levels. Condenser temperatures and pressures are allowed to fluctuate with ambient operating conditions, resulting in reduced compressor load and increased refrigeration capacity. After condensation, liquified refrigerant in the conduit between the receiver and the expansion valve is pressurized without adding heat by a centrifugal pump to a pressure sufficient to suppress flash gas in the conduit.
Abstract: Method and apparatus are disclosed for controlling the pressure in a single compressor refrigeration system, comprising a timer for establishing a selected time period functionally related to the compressor on-off cycle, a pressure detecting means for establishing and detecting an operating suction pressure range in the system for determining when upper and lower limits of the operating pressure range have been exceeded, means for generating a compressor turn-on signal in response to exceeding the upper limit of the operating pressure range, means for generating a compressor turn-off signal in response to exceeding the lower limit of the operating pressure range, and control means receiving the compressor turn-on signal for applying the turn-on signal to the compressor in response to the suction pressure exceeding the operating pressure range upper limit, the control means receiving the compressor turn-off signal and cooperating with the timer for preventing the application of the turn-off signal to the compr
Abstract: Buildings are advantageously heated or heat-conditioned with a heat pump operated with a non-azeotropic mixture of two working fluids. The mixture comprises 99 to 70% by mole of dichlorodifluoromethane (R 12), monochlorodifluoromethane (R 22) or one of the halohydrocarbon azeotropes R 500, R 501 or R 502 with 1 to 30% by mole of trifluoromethane (R 23) or the halohydrocarbon azeotrope R 503.
Abstract: Buildings are advantageously heated or heat-conditioned with a heat pump operated with a non-azeotropic mixture of two working fluids. The mixture comprises 99 to 70% by mole of dichlorodifluoromethane (R 12), monochlorodifluoromethane (R 22) or one of the halohydrocarbon azeotropes R 500, R 501 or R 502 with 1 to 30% by mole of trifluoromethane (R 23) or the halohydrocarbon azeotrope R 503.
Abstract: An air conditioning system and method wherein a central pumping system circulates a heat-exchange liquid (which is water or a glycol solution or other solution called "water") through heating and cooling paths of a refrigeration system and then to and from air-treating units. The fans or blowers of the air-treating units are positioned upstream of the air cooling and heating coils so that the fan heat and pump heat are discharged through the fluid cooler system during cooling load operation, and all of that heat is available for delivery to the air treating units during heating-load operation. The quantity of outside (fresh) air is selected and controlled so that adequate ventilation is provided, and during cold weather so that multi-story buildings may be provided with adequate pressurization to overcome an objectionable inflow of cold air at ground floor levels at entrances and exits.
Abstract: A heat transfer device is described that can be operated as a heat pump or refrigerator, which utilizes a working fluid that is continuously in a liquid state and which has a high temperature-coefficient of expansion near room temperature, to provide a compact and high efficiency heat transfer device for relatively small temperature differences as are encountered in heating or cooling rooms or the like. The heat transfer device includes a pair of heat exchangers that may be coupled respectively to the outdoor and indoor environments, a regenerator connecting the two heat exchangers, a displacer that can move the liquid working fluid through the heat exchangers via the regenerator, and a means for alternately increasing and decreasing the pressure of the working fluid. The liquid working fluid enables efficient heat transfer in a compact unit, and leads to an explosion-proof smooth and quiet machine characteristic of hydraulics.
Type:
Grant
Filed:
May 28, 1980
Date of Patent:
October 12, 1982
Assignee:
The United States of America as represented by the United States Department of Energy
Inventors:
John C. Wheatley, Douglas N. Paulson, Paul C. Allen, William R. Knight, Paul A. Warkentin
Abstract: An electron discharge tube evaporation cooling system in which part of a tube to be cooled is immersed in coolant in a boiler (15), the cooling system further comprising a condenser (18) for vapor generated in the boiler (15), and a coolant reservoir (11). The flow of vapor from the boiler (15) to the condenser (18) experiences resistance in the interconnecting pipe (17), producing in the boiler (15) a back pressure dependent on the dimensions of the pipe (17). In order that a desired level (40) of coolant in the boiler (15) can be obtained for a range of back pressures, the coolant is supplied to the boiler via an overflow system (16) having an adjustable overflow level. The overflow system (16) comprises a chamber (31) open to atmosphere at the top (34) and having at the bottom (33) an opening (36) through which an overflow tube (35) passes.
Abstract: An injector cooler control system which controls the flow of refrigerant from a common receiver that ties a common refrigeration plant to more than one injector cooler systems. The control system limits the amount of liquid refrigerant entering a cooler surge tank by limiting the amount of liquid refrigerant passing from the receiver through an injector valve, thus preventing liquid carryover to the compressor of a common refrigeration plant.
Abstract: A solar operated chemical heat pump useful in both the heating and cooling modes. This system includes an insulated tank containing a fluid which is heated from the exterior. A heat sink in the form of a second tank is also employed. A water-ammonia solution is present in each tank, and conduit means are provided for respectively conducting the vapor of each tank into a bubble plate or similar structure of the remaining tank, this for effecting a thorough dispersion of incoming vapor into the liquid of the respective tanks. Heat from a solar heat source is used to heat the liquid of the first tank to drive off vapor under pressure so that the ammonia gas released can be bubbled through the water of the second tank. This process serves to gradually reduce the ammonium ions in the liquid of the first tank and enables the second tank to serve as a heat sink for the system.
Abstract: In a chemical plant the atmosphere under which a chemical process is performed is contained and continuously circulated by the driving force obtained by the alternate condensation and evaporation of a part of the atmosphere.