Abstract: A fan sink that includes a dual impeller push-pull axial fan and a heat sink to cool a hot electronic device is presented. The axial fan has a hub motor, a first impeller that is radially proximate to the hub motor, and a second impeller that is radially distal to the hub motor, wherein the first impeller pushes air in a first direction and the second impeller pulls air in a second direction. The heat sink is oriented between the axial fan and the hot electronic device such that the hot electronic device, the heat sink, and the axial fan are axially oriented, wherein cool air is forced onto the heat sink by one impeller in the axial fan, and wherein heated air from the heat sink is removed by an other impeller in the axial fan.

Abstract: A fan sink that includes a dual impeller push-pull axial fan and a heat sink to cool a hot electronic device is presented. The axial fan has a hub motor, a first impeller that is radially proximate to the hub motor, and a second impeller that is radially distal to the hub motor, wherein the first impeller pushes air in a first direction and the second impeller pulls air in a second direction. The heat sink is oriented between the axial fan and the hot electronic device such that the hot electronic device, the heat sink, and the axial fan are axially oriented, wherein cool air is forced onto the heat sink by one impeller in the axial fan, and wherein heated air from the heat sink is removed by an other impeller in the axial fan.

Abstract: A fan sink that includes a dual impeller push-pull axial fan and a heat sink to cool a hot electronic device is presented. The axial fan has a hub motor, a first impeller that is radially proximate to the hub motor, and a second impeller that is radially distal to the hub motor, wherein the first impeller pushes air in a first direction and the second impeller pulls air in a second direction. The heat sink is oriented between the axial fan and the hot electronic device such that the hot electronic device, the heat sink, and the axial fan are axially oriented, wherein cool air is forced onto the heat sink by one impeller in the axial fan, and wherein heated air from the heat sink is removed by an other impeller in the axial fan.

Abstract: A heat sink device for conventional memory modules, such as DIMMs, that is configured to be positioned between adjacent memory modules mounted in substantially parallel connectors on a printed circuit board. Each heat sink device includes thermally conductive first and second members configured to thermally couple with electronic components of a conventional memory module. The first and second members may be resiliently biased away from one another so that the resilient bias causes the members to abut respective electronic components when placed between adjacent memory modules. A separate wedge, or a lever-mounted wedge, may be provided for insertion between the members to urge them away from one another and into abutting relationship with electronic components on facing surfaces of the adjacent memory modules. When abutting opposing electronic components, a single heat sink device facilitates heat dissipation from both of the adjacent memory modules.

Abstract: A heat sink device for conventional memory modules, such as DIMMs, that is configured to be positioned between adjacent memory modules mounted in substantially parallel connectors on a printed circuit board. Each heat sink device includes thermally conductive first and second members configured to thermally couple with electronic components of a conventional memory module. The first and second members may be resiliently biased away from one another so that the resilient bias causes the members to abut respective electronic components when placed between adjacent memory modules. A separate wedge, or a lever-mounted wedge, may be provided for insertion between the members to urge them away from one another and into abutting relationship with electronic components on facing surfaces of the adjacent memory modules. When abutting opposing electronic components, a single heat sink device facilitates heat dissipation from both of the adjacent memory modules.

Abstract: A heat sink for distributing a thermal load is disclosed that includes a base receiving the thermal load, the base having a front surface, a back surface, an inner surface, and an outer surface, the outer surface shaped generally as a cylinder and having a flat mounting region, and the inner surface shaped as a cylinder so as to define a cylindrical receiving space, a cylindrical thermal transport connected to the inner surface of the base so as to distribute the thermal load along the inner surface of the base, and heat-dissipating fins connected to the cylindrical thermal transport and extending from the cylindrical thermal transport towards a central axis of the cylindrical receiving space.

Abstract: A heat sink for dissipating a thermal load is disclosed that includes one or more heat sink bases configured around a central axis of the heat sink so as to define an interior space, at least one heat sink base receiving the thermal load, a thermal transport connected to the at least one heat sink base receiving the thermal load so as to distribute the thermal load in the heat sink, and heat-dissipating fins connected to each heat sink base, the heat-dissipating fins extending from each heat sink base into the interior space of the heat sink, each heat-dissipating fin shaped according to the location of the heat-dissipating fin with respect to the location of the thermal load and the location of the distributed thermal load in the heat sink.

Abstract: An enclosure for a rack mounted electronic device is assembled using upper and lower housings which are adjustable one relative to the other to provide increases in enclosure height by fractional increments of a standard unit of height. By providing for fractional growth in height, a user is enabled to upgrade processor, memory and other components without the necessity of replacing the entirety of a device which is in use.

Abstract: A rack engaging member is provided having first and second elements spaced apart one from the other at a predetermined distance which is determined by a first distance at which two openings in a standard rack for receiving electronic devices are spaced apart one from the other. One of the first and second elements is positionable to span the difference in spacing between a pair of rack openings spaced at the first distance one from the other and a different pair of rack openings in the standard rack which are spaced at a second, different, distance one from the other. As a result, devices may be mounted in manners which span the differential spacings of holes between the sets of three provided in the standard rack.

Abstract: A heat sink for distributing a thermal load is disclosed that includes two or more base plates connected and oriented around a central axis of the heat sink, at least one base plate receiving the thermal load, each base plate having thermal transport paths, the thermal transport paths oriented among the base plates so as to have the capability of accepting thermal transports having a plurality of lengths for thermal distribution between at least two base plates, heat-dissipating fins connected to each base plate, the heat-dissipating fins spaced apart in parallel and extending from each base plate towards the central axis of the heat sink, and a thermal transport connected between the base plate receiving the thermal load and at least one other base plate so as to distribute the thermal load among the base plates of the heat sink.

Abstract: A fan sink that includes a dual impeller push-pull axial fan and a heat sink to cool a hot electronic device is presented. The axial fan has a hub motor, a first impeller that is radially proximate to the hub motor, and a second impeller that is radially distal to the hub motor, wherein the first impeller pushes air in a first direction and the second impeller pulls air in a second direction. The heat sink is oriented between the axial fan and the hot electronic device such that the hot electronic device, the heat sink, and the axial fan are axially oriented, wherein cool air is forced onto the heat sink by one impeller in the axial fan, and wherein heated air from the heat sink is removed by an other impeller in the axial fan.

Abstract: A heat sink for distributing a thermal load is disclosed that includes a bottom plate, a top plate, a right plate, and a left plate, the plates connected along edges so as to define a space generally cubical in shape with four closed sides and two open ends; heat-dissipating fins connected to each plate, the fins spaced apart in parallel and extending from each plate towards a central axis of the heat sink; and a thermal transport connected to the plate receiving the thermal load and to at least one of the other plates so as to distribute the thermal load among the plates of the heat sink.

Abstract: A method, apparatus and system are disclosed for utilizing a mechanical air redirection device with air cooled computer assemblies in order to evenly distribute airflow to provide balanced cooling of heat producing components, such as memory chips and boards. The present invention improves the thermal distribution and dissipation of heat for computer and memory systems when some memory devices are removed or left uninstalled.

Abstract: A method, apparatus and system are disclosed for redistributing memory allocation to portions of dynamic random access memory (DRAM) and dual in-line memory module (DIMM) devices that are underutilized, in order to balance memory usage more evenly amongst active devices so as to limit the amount of power and the thermal load consumed by an individual memory component. The disclosed method, apparatus and system are capable of identifying and tracking memory usage to minimize power consumption in a way that lessens the detrimental effects of “throttling” or reduced power modes for memory devices.

Abstract: A system, method and device for managing power distribution on a shared bus system that interconnects multiple devices each containing a signal termination component are disclosed herein. In one embodiment, the method of the invention includes detecting and communicating thermal indicia of one or more of the devices in the shared bus system to a memory controller device. The memory controller includes an on-die termination control circuit for setting and resetting the enablement of the signal termination components of the one or more devices. In a preferred embodiment, the on-die termination control circuit sets and resets the enablement of the signal termination components in accordance with the determined thermal indicia.

Abstract: A heatpipe for cooling an integrated circuit. The heatpipe includes a pipe and radial fins that are formed by extruding a single piece of material, such as heat conducting metal. Each of the radial fins extends away from the pipe and runs (preferably) the length of the pipe. Each radial fin has normally oriented subfins that provide additional heat convection surface areas to the radial fins. Within the pipe are interior fins, also formed during the material extrusion process. The interior fins provide additional conduction cooling to a heat transferring fluid circulating within the pipe.

Abstract: A cooling system includes a cooling fan with an outlet and an inlet and a shroud surrounding at least a portion of the cooling fan. The cooling fan includes a plurality of fan blades, and each fan blade includes an inlet portion and an outlet portion that define an outer periphery of the fan blade. The outlet portion has a profile defined by a radial distance, perpendicular from a central axis of the fan, increasing in a direction towards the outlet. The average angle, relative to a central axis of the fan, of either a profile of the outlet portion or a profile of a portion of the shroud surrounding the outlet portion is between about ±15° of an average angle to the central axis at which a flow of fluid exits the outer periphery of the fan blades or between about 20° and about 70°.

Abstract: A power management server and method for managing power consumption is disclosed. According to one embodiment, a power management server data processing system is provided, where the power management server data processing system comprises a power management communication port to communicatively couple the power management server data processing system to a power-managed server data processing system and a system management processor coupled to the power management communication port. In the described embodiment, the system management processor comprises power management logic configured to receive power management data from the power-managed server data processing system, to generate a power management command utilizing the power management data, and to transmit the power management command to the power-managed server data processing system utilizing the power management communication port. Moreover, the power management data of the described embodiment comprises power management capability data.

Abstract: A distributed method and system for managing power usage among server data processing systems are disclosed. According to one embodiment, a server data processing system of a plurality of server data processing systems is provided, where the server data processing system comprises a power management communication port to communicatively couple the server data processing system to all other server data processing systems of the plurality of server data processing systems and a system management processor coupled to the power management communication port. In the described embodiment, the system management processor comprises communication logic configured to monitor power usage of all the other server data processing systems of the plurality, and power management logic configured to perform a power management operation on the server data processing system based upon the monitored power usage.

Abstract: A power-managed server and method for managing power consumption is disclosed. According to one embodiment, a power-managed server data processing system is provided among a plurality of server data processing systems which comprises a power management communication port to communicatively couple the power-managed server data processing system to a power management server data processing system of the plurality of server data processing systems. The power-managed server data processing system of the described embodiment further comprises a system management processor coupled to the power management communication port which comprises power-managed logic configured to transmit power management data to the power management server data processing system and to receive a power management command utilizing the power management communication port. Moreover, the power management command is generated utilizing the power management data, and the power management data comprises power management capability data.