The invention provides a computer with refrigeration. The computer has a housing, a processor, a refrigeration loop and a fan. The processor is located within the housing at a location distant from an air inlet into the housing. The refrigeration loop includes a compressor, a condenser, and expansion valve and an evaporator located in line one after the other. The evaporator is near the air inlet. The fan causes movement of air through the housing. The air passes over the evaporator to cool the air and the processor is primarily cooled by the air.
An integrated heat dissipating enclosure to provide heat dissipation for computer, power supply or other electronic products such as an integrated circuit on a motherboard, a central processing unit, or a chip on a video adapter. The enclosure has a frame and a cooling cover. The frame is used to carry various internal components or peripherals of a computer. The cooling cover has a plurality of fins spaced from each other by a space. The fins are connected together by a thermal conductive pipe to form an integrated heat dissipating enclosure.
Systems and methods of operating a cooling system provide for determining one or more cooling requirements of a computing system and controlling one or more vent valves of the cooling system based on the cooling requirements. In one approach, the cooling requirements are determined based on operating system state data and/or power management data.
Systems and methods for implementing thermal load balancing are disclosed. In an exemplary embodiment, a thermal load balancing system for a multiprocessor computer having a plurality of processors may comprise a heat sink network having a plurality of local heat sinks. The local heat sinks are thermally coupled to separate processors in the multiprocessor computer. At least one heat pipe thermally couples each of the plurality of local heat sinks in the heat sink network.
A method, apparatus, and system related to thermal management. The method includes reducing a temperature of a stream of air upstream of at least one memory module by a heat absorption component of a refrigeration device, moving the stream of air into contact with at least one surface of the at least one memory module and transferring heat provided by the at least one memory module and a heat rejection component of the refrigeration device to a location downstream of the at least one memory module.
A refrigeration system module including a frame, a heating plate having a fluid inlet and a fluid outlet and a first heat transfer surface, a cooling plate having a fluid inlet and a fluid outlet and a second heat transfer surface, an expansion device disposed between the heating and cooling plates and in fluid communication with the heating plate fluid outlet and the cooling plate fluid inlet, and a hermetic compressor assembly. The compressor assembly is disposed between the heating and cooling plates and has a discharge outlet in fluid communication with the heating plate inlet, and a suction inlet in fluid communication with the cooling plate fluid outlet. The heating plate, the cooling plate, the expansion device and the compressor are fixed to the frame, and the first and second heat transfer surfaces each at least partially define an exterior surface of the module.
