Abstract: A method and apparatus to determine the pressure of a supercritical refrigerant within a heat exchanger of a transcritical vapor compression system. A plurality of measurements, e.g., temperature, are obtained at spaced locations on the heat exchanger and the location of the minimum temperature gradient, i.e., maximum specific heat value of the refrigerant, is determined (“the inflection point”). Obtaining the refrigerant temperature at the inflection point allows the refrigerant pressure to be determined. Alternatively, the temperature of the refrigerant at a second point can be determined together with the change in specific enthalpy between the inflection point and the second point to thereby determine the pressure of the refrigerant. The system can be regulated by controlling the location of the inflection point or by controlling the temperature difference of the refrigerant at the inflection point and a second point, e.g., the outlet of the heat exchanger.

Abstract: A vessel for containing a refrigerant fluid in a vapor compression system. The vessel includes a housing defining a fixed interior volume and an internal structure subdividing the interior volume into a storage chamber and a displacement chamber. The storage chamber is in fluid communication with the vapor compression system and stores both liquid phase and gas phase refrigerant during normal operation of the system. The displacement chamber may be repositionable or have a variable volume wherein varying the volume of the displacement chamber inversely varies the volume of the storage chamber. The volume of the displacement chamber may be controlled by the transfer of thermal energy to a working fluid within the displacement chamber to thereby thermally expand or contract the working fluid.

Abstract: Compact compressors and refrigeration systems that can be used to cool computers, servers, and other electronic equipment. Each compact compressor or refrigeration system includes a compact, substantially enclosed hermitic housing having a simple geometry profile, such as a rectilinear profile, which enables the compact compressor or refrigeration system to be easily inserted within a slot, for example, of an electronic component such as a computer server. In one embodiment, a compact compressor is provided, which includes a motor-compressor unit within the housing, including a stator, a rotor disposed interiorly of the stator, and a compressor mechanism disposed interiorly of the rotor to provide a compact profile.

Abstract: A method and apparatus to determine the pressure of a supercritical refrigerant within a heat exchanger of a transcritical vapor compression system. A plurality of measurements, e.g., temperature, are obtained at spaced locations on the heat exchanger and the location of the minimum temperature gradient, i.e., maximum specific heat value of the refrigerant, is determined (“the inflection point”). Obtaining the refrigerant temperature at the inflection point allows the refrigerant pressure to be determined. Alternatively, the temperature of the refrigerant at a second point can be determined together with the change in specific enthalpy between the inflection point and the second point to thereby determine the pressure of the refrigerant. The system can be regulated by controlling the location of the inflection point or by controlling the temperature difference of the refrigerant at the inflection point and a second point, e.g., the outlet of the heat exchanger.

Abstract: A vessel for containing a refrigerant fluid in a vapor compression system. The vessel includes a housing defining a fixed interior volume and an internal structure subdividing the interior volume into a storage chamber and a displacement chamber. The storage chamber is in fluid communication with the vapor compression system and stores both liquid phase and gas phase refrigerant during normal operation of the system. The displacement chamber may be repositionable or have a variable volume wherein varying the volume of the displacement chamber inversely varies the volume of the storage chamber. The volume of the displacement chamber may be controlled by the transfer of thermal energy to a working fluid within the displacement chamber to thereby thermally expand or contract the working fluid.