Abstract: According to some embodiments, an apparatus may comprise a cold plate comprising a plurality of fins and an impeller comprising a plurality of blades. An output fluid velocity angle defined by the plurality of fins may be aligned to an impeller inlet velocity angle. The impeller inlet velocity angle may be based on an operational speed of the plurality of blades and an angle of the plurality of blades with respect to a center of the impeller.

Abstract: According to some embodiments, a first sealing portion is provided on a valve shaft to seal a chamber. The first sealing portion may, for example, seal the chamber when the valve shaft is inserted a first distance into an opening of the chamber. A second sealing portion may also be provided on the valve shaft to seal the chamber when the valve shaft is inserted a second distance into the opening.

Abstract: According to some embodiments, systems for low cost coaxial liquid cooling may be provided. In some embodiments, a system may comprise an axis. The system may further comprise a heat exchanger coupled to a pump, wherein the heat exchanger and the pump are oriented with respect to the axis.

Abstract: According to some embodiments, an apparatus may comprise a cold plate comprising a plurality of fins and an impeller comprising a plurality of blades. An output fluid velocity angle defined by the plurality of fins may be aligned to an impeller inlet velocity angle. The impeller inlet velocity angle may be based on an operational speed of the plurality of blades and an angle of the plurality of blades with respect to a center of the impeller.

Abstract: According to some embodiments, systems for an integrated cold plate and heat exchanger may be provided. In some embodiments, a device may comprise a cold plate to transfer heat to a fluid and a heat spreader integral with the cold plate, the heat spreader to accept heat from an electronic device. In some embodiments, the heat spreader and the cold plate are monolithic.

Abstract: According to some embodiments, systems for low cost coaxial liquid cooling may be provided. In some embodiments, a system may comprise an axis. The system may further comprise a heat exchanger coupled to a pump, wherein the heat exchanger and the pump are oriented with respect to the axis.

Abstract: An electronic assembly comprising one or more high performance integrated circuits includes at least one high capacity heat sink. The heat sink, which comprises a number of fins projecting substantially radially from a core, is structured to capture air from a fan and to direct the air to optimize heat transfer from the heat sink. The heat sink fins can be formed in different shapes. In one embodiment, the fins are curved. In another embodiment, the fins are bent. In yet another embodiment, the fins are curved and bent. Methods of fabricating heat sinks and electronic assemblies, as well as application of the heat sink to an electronic assembly and to an electronic system, are also described.

Abstract: A system in which a heat exchanger includes a core, a plurality of fins extending outwardly from the core, and an element disposed within the cavity of the core. The heat exchanger also includes a first cap coupled to the first end of the core, and a second cap coupled to the second end of the core where the second cap comprises an inlet and an outlet.

Abstract: According to some embodiments, systems for an integrated pump and cold plate may be provided. In some embodiments, a pump may comprise a housing defining an inlet to accept a fluid and an outlet to evacuate the fluid, an impeller disposed within the housing, wherein the impeller is to move the fluid toward the outlet, a motor to power the impeller, and a cold plate disposed at least partially within the housing. In some embodiments, the pump may also or alternatively comprise a motor to power the impeller, wherein the motor comprises a rotor and at least two magnets disposed within the housing and at least two electromagnetic coils disposed outside of the housing.

Abstract: According to some embodiments, systems for low cost liquid cooling may be provided. In some embodiments, a system may comprise a core having a first end and a second end, wherein the core defines a cavity extending between the first and second ends, a plurality of fins extending outwardly from the core between the first and second ends, an inlet to accept a fluid, an outlet to evacuate the fluid, and a shaped element disposed within the cavity of the core, wherein the shaped element is to direct the fluid within the cavity. According to some embodiments, the system may further comprise a pump that may comprise a housing defining an inlet to accept the fluid and an outlet to evacuate the fluid, an impeller disposed within the housing, wherein the impeller is to move the fluid toward the outlet, a motor to power the impeller, and a cold plate disposed at least partially within the housing.

Abstract: An electronic assembly comprising one or more high performance integrated circuits includes at least one high capacity heat sink. The heat sink, which comprises a number of fins projecting substantially radially from a core, is structured to capture air from a fan and to direct the air to optimize heat transfer from the heat sink. The heat sink fins can be formed in different shapes. In one embodiment, the fins are curved. In another embodiment, the fins are bent. In yet another embodiment, the fins are curved and bent. Methods of fabricating heat sinks and electronic assemblies, as well as application of the heat sink to an electronic assembly and to an electronic system, are also described.

Abstract: A fastener assembly including a base consisting of a pair of motherboard snaps on a first end and a hollow shaft on a second end, the motherboard snaps to be inserted through an aperture of a motherboard. The hollow shaft is inserted through an aperture of a heat sink clip. The base further includes a pair of grooves on an exterior of the shaft. The assembly further including a cap consisting of a hollow interior, an integrated post attached to a base of the interior, and a pair of cantilever snaps. The cap is fitted over the exterior surface of the hollow shaft of the base to secure the clip between the base and the cap. The integrated post of the cap to be inserted into the hollow shaft of the base to deflect the motherboard snaps outward on an opposite side of the motherboard aperture to secure the assembly with the motherboard. The cantilever snaps to be positioned in the grooves of the shaft of the base to secure the cap with the base.

Abstract: An electronic assembly includes an integrated circuit (e.g., a processor) mounted on a substrate (e.g., a motherboard), and a radial heat sink thermally coupled to the integrated circuit. The radial heat sink includes a core having an outer surface, and a plurality of helical fins that extend from the outer surface of the core. The electronic assembly may include a fan positioned near the heat sink. The appropriate angle for the helical fins relative to the longitudinal axis of the heat sink depends in part on the direction of the airflow that is produced by the fan.

Abstract: An electronic assembly includes an integrated circuit (e.g., a processor) mounted on a substrate (e.g., a motherboard), and a radial heat sink thermally coupled to the integrated circuit. The radial heat sink includes a core having an outer surface, and a plurality of helical fins that extend from the outer surface of the core. The electronic assembly may include a fan positioned near the heat sink. The appropriate angle for the helical fins relative to the longitudinal axis of the heat sink depends in part on the direction of the airflow that is produced by the fan.

Abstract: An fastener assembly including a base consisting of a pair of motherboard snaps on a first end and a hollow shaft on a second end, the motherboard snaps to be inserted through an aperture of a motherboard. The hollow shaft is inserted through an aperture of a heat sink clip. The base further includes a pair of grooves on an exterior of the shaft. The assembly further including a cap consisting of a hollow interior, an integrated post attached to a base of the interior, and a pair of cantilever snaps. The cap is fitted over the exterior surface of the hollow shaft of the base to secure the clip between the base and the cap. The integrated post of the cap to be inserted into the hollow shaft of the base to deflect the motherboard snaps outward on an opposite side of the motherboard aperture to secure the assembly with the motherboard, and the cantilever snaps to be positioned in the grooves of the shaft of the base to secure the cap with the base.

Abstract: An electronic assembly comprising one or more high performance integrated circuits includes at least one high capacity heat sink. The heat sink, which comprises a number of fins projecting substantially radially from a core, is structured to capture air from a fan and to direct the air to optimize heat transfer from the heat sink. The heat sink fins can be formed in different shapes. In one embodiment, the fins are curved. In another embodiment, the fins are bent. In yet another embodiment, the fins are curved and bent. Methods of fabricating heat sinks and electronic assemblies, as well as application of the heat sink to an electronic assembly and to an electronic system, are also described.

Abstract: An electronic assembly comprising one or more high performance integrated circuits includes at least one high capacity heat sink. The heat sink, which comprises a number of fins projecting substantially radially from a core, is structured to capture air from a fan and to direct the air to optimize heat transfer from the heat sink. The heat sink fins can be formed in different shapes. In one embodiment, the fins are curved. In another embodiment, the fins are bent. In yet another embodiment, the fins are curved and bent. Methods of fabricating heat sinks and electronic assemblies, as well as application of the heat sink to an electronic assembly and to an electronic system, are also described.

Abstract: An electronic assembly comprising one or more high performance integrated circuits includes at least one high capacity heat sink. The heat sink, which comprises a number of fins projecting substantially radially from a core, is structured to capture air from a fan and to direct the air to optimize heat transfer from the heat sink. The heat sink fins can be formed in different shapes. In one embodiment, the fins are curved. In another embodiment, the fins are bent. In yet another embodiment, the fins are curved and bent. Methods of fabricating heat sinks and electronic assemblies, as well as application of the heat sink to an electronic assembly and to an electronic system, are also described.

Abstract: Non-prismatic radial folded fin heat sinks include fin arrays comprised of folded fins joined to a thermally conductive central core. The fin arrays can have either a constant or variable bend radius. The non-prismatic radial folded fins can be made by stamping patterns into sheet metal prior to folding the sheet metal in opposite directions at various intervals to form outer and inner folds. By arranging the fins in a non-prismatic radial pattern around the central core, airflow generated by an overhead fan is better utilized, thus improving the cooling effect of the device.

Abstract: A heat sink (and method of forming a heat sink) is provided that includes a core having a central axis and a plurality of cooling fins arranged about the core. Each fin has a base and a tip. The fins may be shaped to capture a tangential component of air from the fan. At least one portion (such as upper portion) of the fins may be bent. A lower portion of each fin may also be bent.