Patent application number | Description | Published |
20130120926 | USER-SERVICEABLE LIQUID DIMM COOLING SYSTEM - A cooling system for a memory module comprises a heat conduction assembly for conducting heat from the memory module to liquid-cooled mounting blocks. In one embodiment, each heat conduction assembly includes a frame having opposing first and second supports, first and second heat spreader plates each extending from the first support to the second support, and a pair of flattened heat pipes each extending along a respective one of the heat spreader plates from the first support to the second support. The liquid-cooled mounting blocks releasably support the heat conduction assembly over a memory module socket with the memory module between the heat spreader plates. | 05-16-2013 |
20130126145 | HEAT SINK WITH ORIENTABLE FINS - A heat sink comprises a first thermally conductive base having a first face to thermally engage a heat-generating electronic component and a second thermally conductive base with a plurality of fins on a first face and a second face to engage the first base. The fins on the second base are positionable in either of two orientations relative to the heat-generating electronic component to which the heat sink is coupled. The fins are selectively placed in the orientation that best utilizes the direction of air flow available to the heat sink. The orientable fins of the heat sink afford flexibility in arranging the heat-generating electronic component on a circuit board or in arranging a circuit board within a computer chassis. | 05-23-2013 |
20130133859 | HEAT SINK WITH HEAT BUS AND FIN STRUCTURE - A heat sink to remove heat from a processor within a chassis to air moving through a fin structure on the heat sink. An embodiment of the heat sink comprises a heat bus engaging the processor to conduct heat from the processor to a fin structure having interconnected, repeating cellular air channels. A U-shaped heat bus comprises a base and first and second legs extending therefrom connected to opposite sides of the fin structure. An embodiment of the heat bus has a solid conductive core to conductively transfer heat from the processor through the base and the first and second legs to sides of the fin structure. Alternately, an embodiment of the heat bus has a hollow core containing a fluid to evaporatively transfer heat from the processor through the base and the first and second legs to sides of the fin structure. | 05-30-2013 |
20130135812 | LIQUID-COOLING MEMORY MODULES WITH LIQUID FLOW PIPES BETWEEN MEMORY MODULE SOCKETS - A liquid-cooled computer memory system includes first and second blocks in fluid communication with a chilled liquid source. A plurality of spaced-apart heat transfer pipes extend along a system board between memory module sockets from the first manifold block to the second manifold block. The heat transfer pipes may be liquid flow pipes circulating the chilled liquid between the memory module sockets. Alternatively, the heat transfer pipes may be closed heat pipes that conduct heat from the memory modules to the liquid-cooled blocks. A separate heat spreader is provided to thermally bridge each memory module to the adjacent heat transfer pipes. | 05-30-2013 |
20130138262 | HEAT SINK WITH ORIENTABLE FINS - A heat sink comprises a plurality of fins that may be positioned in a plurality of orientations relative to a heat-generating electronic component to which the heat sink is thermally coupled. A controller may be used to detect an elevated processor temperature and to activate a drive member to automatically adjust the orientation of fins on the heat sink. The fins may be moved and aligned with an air flow made over the heat sink. The adjustable-fin heat sink affords added flexibility in arranging a processor or other heat-generating electronic component on a circuit board. The orientation or position of the heat sink fins may also be automatically changed in response to a change in the air flow direction as manifested by a rise in the temperature of the heat sink or the heat-generating member. | 05-30-2013 |
20130168068 | THERMALLY ENHANCED COLD PLATE HAVING HIGH CONDUCTIVITY THERMAL TRANSFER PATHS - A cold plate comprises a cold plate body having a base for thermally engaging a heat-generating device, a plurality of internal channels extending through the cold plate body for the passage of a liquid coolant, a first region between the base and the plurality of internal channels, and a second region between the plurality of internal channels and a top that is generally opposite the base from the plurality of internal channels. The cold plate body is made from a first thermally conductive material. The cold plate also comprises at least one thermally conductive member extending around the plurality of channels from the first region below the plurality of channels to the second region above the plurality of channels. The at least one thermally conductive member has a greater thermal conductivity than the first thermally conductive material to move heat from the first region to the second region. | 07-04-2013 |
20130177391 | ELECTROSTATIC CONTROL OF AIR FLOW TO THE INLET OPENING OF AN AXIAL FAN - A method of modifying the airflow to the inlet of an axial fan comprises operating an axial fan to move air longitudinally through an air inlet opening of the axial fan, and, during operation of the axial fan, applying an electrical potential between an emitter and a collector to cause ionic air movement radially outwardly away from a central axis of the axial fan, wherein the radially outward air movement is caused upstream of the axial fan before the air reaches the air inlet opening. | 07-11-2013 |
20140230234 | ELECTROHYDRODYNAMIC AIRFLOW ACROSS A HEAT SINK USING A NON-PLANAR ION EMITTER ARRAY - A method of cooling a heat generating device includes positioning a base of an electronically conductive heat sink in thermal communication with a heat generating device, wherein the heat sink includes a plurality of fins extending in a longitudinal direction from a first end to a second end, and coupling the heat sink to ground. The method further includes emitting ions from a plurality of ion emitter elements disposed in a non-planar pattern along the first ends of the plurality of fins, wherein at least three ion emitter elements are equidistant from the first end of the nearest fin and are positioned in an arc having an axis that extends along the first end of the nearest fin. | 08-21-2014 |