Abstract: Various heat sinks, method of use and manufacture thereof are disclosed. In one aspect, a method of providing thermal management for a circuit device is provided. The method includes placing a heat sink in thermal contact with the circuit device wherein the heat sink includes a base member in thermal contact with the circuit device, a first shell coupled to the base member that includes a first inclined internal surface, a lower end and first plurality of orifices at the lower end to enable a fluid to transit the first shell, and at least one additional shell coupled to the base member and nested within the first shell. The at least one additional shell includes a second inclined internal surface and a second plurality of orifices to enable the fluid to transit the at least one additional shell. The fluid is moved through the first shell and the at least one additional shell.

Abstract: Various thermal interface structures and methods are disclosed. In one aspect, a method of manufacturing is provided. The method includes providing plural carbon nanotubes in a thermal interface structure. The thermal interface structure is soldered to a side of a semiconductor chip. In another aspect, an apparatus is provided. The apparatus includes a thermal interface structure that has plural carbon nanotubes. A semiconductor chip is soldered to the thermal interface structure.

Abstract: Various apparatus and methods for thermally managing a heat generating device. In one aspect, a method of thermally managing a heat generating device is provided that includes placing a heat exchanger in thermal communication with the heat generating device. The heat exchanger has an interior space. A membrane is in the interior space between a first chamber and a second chamber. The membrane has a gas impermeable portion and at least one gas permeable portion to enable vapor bubbles in the second chamber to pass through the membrane at the at least one gas permeable portion and into the first chamber. A liquid is moved through the second chamber.

Abstract: Various semiconductor chip thermal interface material methods and apparatus are disclosed. In one aspect, a method of establishing thermal contact between a first semiconductor chip and a heat spreader is provided. The method includes placing a thermal interface material layer containing a support structure on the first semiconductor chip. The heat spreader is positioned proximate the thermal interface material layer. The thermal interface material layer is reflowed to establish thermal contact with both the first semiconductor chip and the heat spreader.

Abstract: A semiconductor device includes first and second stacked semiconductor dies on a substrate. A lid having a plurality of fins extending downwardly into the cavity is mounted on the substrate to encapsulate the semiconductor dies. At least some of the fins are longer than other ones of said fins. The lid is attached to the substrate, with the longer fins extending downwardly above a region of the substrate not occupied by the first die. The shorter fins extend downwardly above a region of said first die not covered by said second die. A thermal interface material fills the remainder of the cavity and is in thermal communication with both dies, the substrate and the fins. The lid may be molded from metal. The lid may be bonded to the topmost die, using a thermal bonding material that may be liquid metal, or the like.

Abstract: A thermal management device for a circuit substrate having at least a first heat generating component and at least a second heat generating component, the thermal management device includes a first thermal spreader and a second thermal spreader. The second thermal spreader is mountable to the circuit substrate to thermally couple with the second heat generating component. Additionally, the second thermal spreader is adapted to couple to the first thermal spreader to thermally couple the first thermal spreader to the first heat generating component when the second thermal spreader is mounted to the circuit substrate. The thermal management device also includes a bias device that is coupled to the first thermal spreader and the second thermal spreader and is adapted to maintain the thermal coupling between the first thermal spreader and the first heat generating component when the second thermal spreader is mounted to the circuit substrate.

Abstract: Various apparatus and methods of removing heat from devices in a computing device. In one aspect, a method of removing heat from a semiconductor chip in an enclosure of a computing device is provided. Heat from the semiconductor chip is transferred using a heat sink that is thermally coupled to the semiconductor chip. Air is moved using an air mover positioned in the enclosure. The air mover is operable to move the air past the heat sink and recycle at least a portion of the air to again pass the heat sink.

Abstract: Various circuit board fluid cooling systems and methods of using the same are disclosed. In one aspect, a method of manufacturing is provided that includes coupling a first member to a circuit board where the first member has a first opening with a first internal footprint. A heat exchanger is removably coupled to the first member to transfer heat from at least one component of the circuit board. The heat exchanger has an external footprint adapted so that at least a portion of the heat exchanger fits in the first opening. A plate is coupled to the circuit board to transfer heat from at least one component of the circuit board. A fluid supply line and a fluid return line are coupled to the heat exchanger such that one of the fluid supply line and the fluid return line is thermal contact with the plate to transfer heat therefrom.

Abstract: Provided are systems, methods, and computer program products for regulating power consumption in application-specific integrated circuits (ASICs)—such as, for example, a graphics processing unit. In such a method, a value of a leakage current of an ASIC is received from computer-readable information contained in the ASIC. One or more operational parameters of the ASIC—such as, for example, a supply voltage to the ASIC, a engine speed of the ASIC, and/or a fan speed of a fan used to cool the ASIC—are adjusted based on the value of the leakage current of the ASIC. Optionally, the one or more operational parameters may also be adjusted based on a type of application running on the ASIC. In addition, a supply voltage to the ASIC may (optionally) be shut off if the temperature of the ASIC exceeds a threshold.

Abstract: The present invention generally relates to a multidimensional thermal management device for an integrated circuit chip, and more particularly, to thermal management devices with a synthetic jet ejector adapted to operate along a hollow fin and a fin with cross-flow heat exchanger tubes. A thermal management device 50, a new circuit assembly 100 equipped with the new thermal management device 50, and a new guide for a synthetic jet ejector 20 for adapting the synthetic jet ejector technology to the new thermal management device 50 and associated circuit assembly 100 are disclosed.

Abstract: The present disclosure relates to thermal management apparatus for a circuit substrate having heat generating components mounted on one or both sides thereof. The apparatus and method includes a circuit assembly having a first thermally conductive layer disposed on each side of the circuit substrate and being thermally coupled to one or more heat generating components of the circuit substrate. The apparatus and method includes a second thermally conductive layer disposed on each side of the circuit substrate and being thermally coupled to the first thermally conductive layer. The first thermally conductive layer and the thermally conductive layer can be shaped, sized, and/or configured to provide cooling of the one or more heat generating components disposed on each side of the circuit substrate by transferring and spreading the heat to the outside of the circuit assembly.

Abstract: A localized refrigerator apparatus for a thermal management device includes a chamber having an evaporation portion and a condensation portion. The evaporation portion is adapted to thermally couple to a heat generating device. A fluid housed in the chamber and is adapted to facilitate heat transfer between the evaporation portion and the condensation portion by an evaporation and condensation cycle. The thermal management device also includes a thermoelectric cooler thermally coupled to the condensation portion.

Abstract: A device to thermally couple a thermal management apparatus to at least one heat generating component of a circuit substrate includes at least a first portion that is adapted to couple to the thermal management apparatus, and at least a second portion that is adapted to couple to the thermal management apparatus. The first portion and the second portion may be symmetrically arranged relative to each other. The first portion and the second portion are adapted to thermally couple the thermal management apparatus to the heat generating component with a first spring bias. The first portion and the second portion are further adapted to maintain the thermal management apparatus thermally coupled to the heat generating component with a second spring bias.

Abstract: Various semiconductor chip thermal management systems and methods are disclosed. In one aspect, a method of manufacturing is provided that includes coupling a semiconductor chip to a substrate and coupling a diamond heat spreader that has a thermoelectric cooler to the semiconductor chip. A vapor chamber is coupled to the diamond heat spreader.

Abstract: A field reconfigurable muxponder for use in an optical transport system. The muxponder includes one or more tributary cards, where each tributary card is adapted to receive an optical data signal and conditions the optical data signal into an intermediate data signal constituted in accordance with a tributary interface format. In this way, the muxponder is able to aggregate optical data signals having different protocols and/or different data rates. The muxponder further includes a chassis that is adapted to receive a predefined number of tributary cards and outputs an optical system signal independently from the availability of the optical data signals from the tributary cards. The tributary cards and the chassis integrally form one line card.

Abstract: A configurable multiple inlet thermal management device, such as an air-mover or passive heat sink, for electronic devices. The thermal management device is arranged on a computing device or on a component of a computing device or similar, such as an expansion module or alike, so that incoming air flow decreases the temperature of the heat producing components. In order to provide best possible air flow the air-mover comprises blade design that pressurizes the air flow from at least one side of the air-mover component. The air-mover includes removable covers for providing the openings required for intake air from the desired direction and for providing a fan wind. Depending on the application the openings may be permanently opened or closed. The intake air flow is then directed in form of fan wind towards the heat producing elements.

Abstract: A thermal management device for a circuit substrate having at least a first heat generating component and at least a second heat generating component, the thermal management device includes a first thermal spreader and a second thermal spreader. The second thermal spreader is mountable to the circuit substrate to thermally couple with the second heat generating component. Additionally, the second thermal spreader is adapted to couple to the first thermal spreader to thermally couple the first thermal spreader to the first heat generating component when the second thermal spreader is mounted to the circuit substrate. The thermal management device also includes a bias device that is coupled to the first thermal spreader and the second thermal spreader and is adapted to maintain the thermal coupling between the first thermal spreader and the first heat generating component when the second thermal spreader is mounted to the circuit substrate.

Abstract: A thermal management device for a circuit substrate having at least a first heat generating component and at least a second heat generating component, the thermal management device includes a first thermal spreader and a second thermal spreader. The second thermal spreader is mountable to the circuit substrate to thermally couple with the second heat generating component. Additionally, the second thermal spreader is adapted to couple to the first thermal spreader to thermally couple the first thermal spreader to the first heat generating component when the second thermal spreader is mounted to the circuit substrate. The thermal management device also includes a bias device that is coupled to the first thermal spreader and the second thermal spreader and is adapted to maintain the thermal coupling between the first thermal spreader and the first heat generating component when the second thermal spreader is mounted to the circuit substrate.

Abstract: The present disclosure relates to heat transfer thermal management device utilizing varied methods of heat transfer to cool a heat generating component from a circuit assembly or any other embodiment where a heat generating component can be functionally and operatively coupled. In an embodiment, the vapor configuration is modified to include fins that define a cross-flow heat exchanger there the vapor from the vapor chamber serves as the fluid in the vertical cross-flow in the heat exchanger and natural or forced cooling air serves as the horizontal cross-flow for the heat exchanger.

Abstract: The present disclosure relates to heat transfer thermal management device utilizing varied methods of heat transfer to cool a heat generating component from a circuit assembly or any other embodiment where a heat generating component can be functionally and operatively coupled. In a proposed embodiment, at least one heat pipe is used to transfer heat from the condensation portion of a vapor chamber to cool a bottom portion of a finned heat dissipation space and transfer the heat to a colder location on the heat fins. In another proposed embodiment, the water vapor chamber is placed in a heat sink and is adapted to thermally connect to at least one heat pipe.