A radiative heatsink includes a cold plate, a radiator mounted to the cold plate and a thermal compound located between and coupling the heat source to the cold plate. The thermal compound converts a portion of a first phononic thermal energy from the heat source into a first photonic near-field and a first photonic far-field thermal radiation and transfers the first photonic near-field, the first photonic far-field and the remaining of the first phononic thermal energy to the cold plate. The cold plate combines the first photonic near-field, the first photonic far-field and the remaining first phononic thermal energy into a second phononic thermal energy and provides the second phononic thermal energy to the radiator. The radiator converts the second phononic thermal energy into a second photonic near-field and a second photonic far-field and emits the second photonic near-field or the second photonic far-field such that cold plate is regenerated.

The present disclosure provides a connector assembly including a receptacle connector, a shielding shell and a heat sink. The shielding shell covers the receptacle connector. The heat sink is assembled to the shielding shell and includes a heat dissipating base plate and a heat dissipating fin soldered on the heat dissipating base plate. The heat dissipating base plate has a soldering region on which solder is provided and a recessed channel provided between a rim of the heat dissipating base plate and an outer periphery of the soldering region. The solder is provided within the soldering region in a manner such that a face of the soldering region is covered by the solder.

A connector assembly includes a receptacle connector, a shielding cage, a heat sink and a clip. The shielding cage covers the receptacle connector. The clip assembles the heat sink to the shielding cage, is integrally formed by a metal sheet and includes a fixed plate, a movable plate and a plate spring. The fixed plate is provided to the shielding cage, and the movable plate is provided to a side surface of the heat sink. Two ends of the plate spring are respectively connected to the fixed plate and the movable plate, and the movable plate is capable of moving relative to the fixed plate by means of the plate spring.

The embodiments include a stackable computing device that includes an integrated heatsink and antenna structure and a housing structure. The housing structure includes a housing casing that surrounds the integrated heatsink and antenna structure. The integrated heatsink and antenna structure includes a heatsink base and one or more radio frequency (RF) antenna portions. The heatsink base includes a connector port that provides an interface between components of the computing device and other computing or peripheral devices. For example, the heatsink base may include platform that is configured to have circuitry fixedly secured on a first side of the platform with a connector of the circuitry aligned with an aperture of the connector port such that a connection to the circuitry is accepted by circuitry of another computing device.

The power conversion device includes: a housing; an electric wiring board stored in the housing; a first heat generating component provided on the one surface of the electric wiring board; a second heat generating component which has a lower heat generation density than the first heat generating component and of which a protruding height from the electric wiring board is equal to or smaller than a protruding height of the first heat generating component, the second heat generating component being provided on the one surface of the electric wiring board; and a third heat generating component which has a lower heat generation density than the first heat generating component and of which a protruding height from the electric wiring board is greater than the protruding height of the first heat generating component, the third heat generating component being provided on another surface of the electric wiring board.

A power supply includes a battery; an inverter that controls an output voltage of the battery; an air-cooler that cools the battery and the inverter with cooling air; and a case that houses the battery, the inverter, and the air-cooler.

A heat dissipation structure includes a heat sink, a first thermal interface material, a second thermal interface material, a circuit board and a circuit element. The first thermal interface material is connected to the heat sink and has fluidity. The second thermal interface material is connected to the first thermal interface material and has no fluidity. The circuit board is connected to the second thermal interface material and has an opening, a top board surface and a bottom board surface. The circuit element includes a convex portion and a base portion. The convex portion has a top convex surface and is disposed in the opening. The base portion is connected to the convex portion and the bottom board surface. The second thermal interface material is connected to the top board surface and the top convex surface.

The present invention provides an in-vehicle electronic control device which further improves heat dissipation by forming a protrusion extending toward an electronic component on an inner surface of a cover portion formed of a highly thermally conductive resin in consideration of orientation of a filling material contained in the highly thermally conductive resin. An in-vehicle electronic control device of the present invention includes: a circuit board on which an electronic component is mounted; a base portion in which the circuit board is installed; and a cover portion with which the circuit board is covered together with the base portion, which is formed of a resin containing a filling material, and which has a protrusion protruding toward the electronic component, in which the protrusion is formed of a resin containing a filling material and a width of the protrusion is smaller than a width of the electronic component.

A server device includes a casing, an electronic assembly, a cover, and a heat dissipation device. The electronic assembly includes a circuit board and at least one heat source. The circuit board is disposed on the casing, and the heat source is disposed on the circuit board. The cover is removably disposed on the casing. The heat dissipation device includes at least one air cooling heat exchanger and at least one liquid cooling heat exchanger. The air cooling heat exchanger is fixed on and thermally coupled with the heat source. The liquid cooling heat exchanger is fixed on the cover and thermally coupled with the air cooling heat exchanger.

A server device includes a casing, an electronic assembly, a cover, and a heat dissipation device. The electronic assembly includes a circuit board and at least one heat source. The circuit board is disposed on the casing, and the heat source is disposed on the circuit board. The cover is slidably disposed on the casing. The heat dissipation device includes at least one air cooling heat exchanger and at least one liquid cooling heat exchanger. The air cooling heat exchanger is fixed on and thermally coupled with the heat source. The liquid cooling heat exchanger is fixed on the cover and thermally coupled with the air cooling heat exchanger.