Disclosed embodiments include composite compliant pillars in a micro-structure array that extend at a non-orthogonal angle from a heat-sink base. The array is deployed against an integrated-circuit device package to deflect the composite compliant pillar array under conditions where heat-transfer performance is agnostic to dynamic non-planarity of the integrated-circuit device package.

A thermal switch having an on-state and an off-state is provided. First and second plates are composed from a thermally conductive material. The first and second plates are connected to form an internal cavity having a channel defining a gap between the first and second plate. The first reservoir is coupled to the channel and contains a thermally conductive liquid. The actuator is coupled to the first reservoir and the channel and is moveable between a first state and a second state corresponding to the on-state and the off-state of the thermal switch, respectively. Thermally conductive liquid is allowed to flow from the first reservoir to the channel when the actuator is in the first state and allowed to flow from the channel to the first reservoir when the actuator is in the second state.

An electronic device includes a heat-generating electronic component, a heat spreader and a heat sink. The heat spreader has an area at least about 4 times greater than the heat-generating component. A first surface of the heat spreader is in thermal contact with the first surface of the heat-generating component along a first, non-dielectric interface. The heat sink has greater mass than the heat spreader and comprises one or more layers of thermally conductive material. A first surface of the heat sink is in thermal contact with the second surface of the heat spreader along a second interface having greater area than the first interface. Dielectric thermal interface material is provided at the second interface in direct contact with the heat spreader and the heat sink, such that the second interface is dielectric.

Methods of producing coolant-cooled heat sinks with a coolant-carrying compartment between a cover and a heat transfer base are provided. The heat transfer base includes a heat transfer surface to couple to a component to be cooled, and a plurality of thermally-conductive fins extending into the coolant-carrying compartment from a surface of the heat transfer base opposite to the heat transfer surface. The method includes positioning a screen with openings over the plurality of thermally-conductive fins, between the plurality of thermally-conductive fins and the cover, and providing a joining material over the screen, between the screen and the cover. The method also includes joining the plurality of thermally-conductive fins to the cover across the screen using the joining material, where the screen facilitates retaining the joining material over the plurality of thermally-conductive fins during the joining.

A thermal switch having an on-state and an off-state is provided. First and second plates are composed from a thermally conductive material. The first and second plates are connected to form an internal cavity having a channel defining a gap between the first and second plate. The first reservoir is coupled to the channel and contains a thermally conductive liquid. The actuator is coupled to the first reservoir and the channel and is moveable between a first state and a second state corresponding to the on-state and the off-state of the thermal switch, respectively. Thermally conductive liquid is allowed to flow from the first reservoir to the channel when the actuator is in the first state and allowed to flow from the channel to the first reservoir when the actuator is in the second state.

A method for controlling thermal conductivity between two thermal masses includes thermally contacting a first conduction body with a heat source, thermally contacting a second conduction body with a heat sink, and thermally contacting the second conduction body with the first conduction body by moving the first conduction body between a first position and a second position with a thermal expansion component. The thermal expansion component moves the first conduction body between the first position and the second position at a predetermined temperature and heat is conducted from the heat source to the heat sink through the first and second conduction bodies.

A heat dissipation device for an electronic device is provided. The heat dissipation device comprises a heat conducting cover configured to be disposed on an electronic device, the heat conducting cover forming a closed cavity; and a heat absorbing material filler located within the closed cavity as defined by the heat conducting cover. With a temperature increase of the electronic device, the heat absorbing material filler is configured to deform structurally, to absorb heat generated by the electronic device.

The present invention relates to a thermal conductive cylinder installed with U-type core piping and loop piping for being installed within natural thermal storage body or artificial thermal storage body; wherein the piping segments of fluid inlet terminal and/or outlet terminal of the U-type core piping and loop piping are directly made of thermal insulating material, or thermal insulating structure is installed between the inlet terminal and the outlet terminal; so as to prevent thermal energy loss between adjacent piping segments on the same side when thermal conductive fluid with temperature difference passing through.

Embodiments herein relate to systems, apparatuses, processing, and techniques related to patterning one or more sides of a thin film capacitor (TFC) sheet, where the TFC sheet has a first side and a second side opposite the first side. The first side and the second side of the TFC sheet are metal and are separated by a dielectric layer, and the patterned TFC sheet is to provide at least one of a capacitor or a routing feature on a first side of a substrate that has the first side and a second side opposite the first side.

A heat spreader apparatus, testing system, method may be used to test an electronic device. The heat spreader may include a hollow housing. The hollow housing may define an interior chamber. The hollow housing may include a contact surface. The heat spreader may include a working fluid. The working fluid may be included in the interior chamber. The hollow housing may be configured to be physically compliant. The hollow housing may be physically compliant such that the hollow housing conforms to the shape of a testing surface in response to an applied pressure. The testing surface may be a top surface of a semiconductor. The testing surface may be curved or otherwise lack uniformity. The hollow housing may conform to the curvature or lack of uniformity of the testing surface such that minimal gaps exist between the hollow housing and the surface.