Abstract: A cold plate includes two flow-wise isolated coolant (or refrigerant) passages (or sets of passages) for use in conjunction with separate refrigeration systems. The cold plate passages do not permit flow communication between distinct coolant (or refrigerant) paths. This permits two distinct cooling systems to operate in a redundant manner. Nonetheless, flow isolation is achieved while still maintaining tight thermal coupling between each path and the object, such as an electronic computer processor module, to be cooled.

Abstract: A cold plate includes two flow-wise isolated coolant (or refrigerant) passages (or sets of passages) for use in conjunction with separate refrigeration systems. The cold plate passages do not permit flow communication between distinct coolant (or refrigerant) paths. This permits two distinct cooling systems to operate in a redundant manner. Nonetheless, flow isolation is achieved while still maintaining tight thermal coupling between each path and the object, such as an electronic computer processor module, to be cooled.

Abstract: A parallel plate heat sink used in conjunction with an air moving device which provides an annular flow of air against the heat sink is further provided with enhanced flow deflector means which selectively block potential exhaust paths so as to redirect the flow of air to the region under a central hub of the fan. This transforms otherwise stagnant air volume in the center of the heat sink into a primary cooling region thus lowering conduction losses and electronic component junction temperatures.

Abstract: A parallel plate heat sink used in conjunction with an air moving device which provides an annular flow of air against the heat sink is further provided with enhanced flow deflector means which selectively block potential exhaust paths so as to redirect the flow of air to the region under a central hub of the fan. This transforms otherwise stagnant air volume in the center of the heat sink into a primary cooling region thus lowering conduction losses and electronic component junction temperatures.

Abstract: A parallel plate heat sink used in conjunction with an air moving device which provides an annular flow of air against the heat sink is further provided with enhanced flow deflector means which selectively block potential exhaust paths so as to redirect the flow of air to the region under a central hub of the fan. This transforms otherwise stagnant air volume in the center of the heat sink into a primary cooling region thus lowering conduction losses and electronic component junction temperatures.

Abstract: An integrated coolant fluid supply and exhaust distribution pathdefining structure is employed to provide a substantially planar cooling system for an electronic assembly which includes a substrate having electronic modules or electronic chips disposed thereon. The pathdefining structure includes interleaved supply and exhaust channels with the supply channels including apertures disposed adjacent to heat sink shafts which are connected to planar heat sink structures in thermal contact with chips or modules being cooled. The pathdefining structure produces a fluid flow path which is initially aligned with the surface area enhancing heat sink shafts and which exits therefrom in a plurality of directions which ultimately lead to the exhaust channels provided in the path-defining structure. The assembly, which includes an exterior housing and the substrate, provides a compact cooling mechanism for electronic components.

Abstract: A heat exchanger, especially for use in conjunction with a wide range of computer systems ranging from work stations to massively parallel processors is employable with both air and water cooling systems. In particular, a heat exchanger is provided which is convertible from a heat sink modality to an air cooling modality and finally to a liquid cooling modality in response to either increased performance demands or an increase in the number of processors or circuit components employed. The conversion may be carried out in the field and provides a flexible and less costly upgradeability path for data processing customers.

Abstract: A configuration of solid state thermoelectric heat transfer or removal elements is provided to enhance the rate and amount of heat removal from electrical and electronic circuit devices. By rotating the thermoelectric heat transfer modules ninety degrees and by disposing them between the interdigitated fingers of a cold plate and a heat transfer plate possessing fins, improved thermal transfer is produced without the necessity of liquid coolants or moving part cooling devices. Accordingly, a method and apparatus is provided for enhancing heat transfer using thermoelectric modules. One embodiment of the present invention is particularly seen to be easy to manufacture. Additionally, this embodiment also possesses desirable heat transfer characteristics in terms of the cross sections of thermally conductive components.

Abstract: Cooling module geometry provides a method for controlling local condensation for liquid impingement two-phase cooling of electrical and/or electronic circuit chips. The method and apparatus described herein uses vapor condensation in the exhaust flow from each chip site within a multi-chip module which utilizes direct liquid impingement with phase change.

Abstract: A convertible cooling module, especially for use in conjunction with a wide range of computer systems ranging from workstations to massively parallel processors is employable with both air and water cooling systems. In particular, a cooling module is convertible from a heat sink modality to an air cooling modality, and finally to a liquid cooling modality in response to either increased performance demands or an increase in the number of processors or circuit components employed. The conversion may be carried out in the field and provides a flexible and less costly upgradeability path for computer customers.

Abstract: Electronic chips are cooled to an efficient operating temperature by engaging their exposed planar surfaces with a heat sink assembly. The heat sink assembly is a part of the cold end heat sink of a thermoacoustic heat pump that utilizes either traveling wave or standing wave heat pumping to transport heat from the cold end heat exchanger to the warm end heat exchanger, utilizing a coaxial pulse tube refrigerator to pump or transport the heat from the electronic chips and the cold end heat exchanger.

Abstract: A circuit module that contains a planar array of chips has an improved fin assembly that transfers heat to a liquid coolant that is circulated through the fins in a single pass so that there is a tendency for the upstream edge of the fins to run cold and the downstream edge to run hot. The module can be immersed in the coolant. A shroud on the fins confines the coolant flow to channels defined by the fins, the shroud, and the base of the fins. The fin assembly is constructed so that the coolant channels are narrowed as a function of the temperature of the liquid coolant. The narrowing channels increase the coolant velocity and thereby improves the heat transfer at what would otherwise become the hot end of the module. The coolant velocity is increased at the appropriate rate to maintain equal cooling along the direction of coolant flow.