The present invention relates to a heat dissipation device for an electronic element, the heat dissipation device including a first chamber in which a printed circuit board having heating elements mounted thereon is disposed, a second chamber configured to exchange heat with heat transferred from the first chamber and configured such that an injection part configured to inject a refrigerant and a refrigerant supply part configured to supply the refrigerant to the injection part are disposed in the second chamber, a heat transfer part disposed between the first chamber and the second chamber and configured to receive heat from the heating elements of the first chamber and supply the heat to the second chamber, and a condensing part configured to condense the refrigerant injected into the second chamber, in which a plurality of evaporation-inducing ribs is provided on a surface of the heat transfer part exposed to the second chamber and allows the liquid refrigerant injected by the injection part to be adsorbed and then flow downward along wave-pattern flow paths having zigzag shapes, thereby providing an advantage of improving heat dissipation performance without increasing a size thereof.

An apparatus includes a motherboard with a processor socket, a load frame connected to the motherboard adjacent to at least two sides of the processor socket, and a processor retainer rotatably connected to the load frame, the processor retainer being positionable in a closed position, an opened position, and an installation position. The processor retainer extends over the processor socket when the processor retainer is in the closed position.

Electronic equipment includes a plurality of heat generating elements, a single heat sink, and a single cover. The heat generating elements are arranged adjacent to one another in a one-dimensional array in a predetermined alignment direction. The faces of the heat generating elements on one side are fixed directly or indirectly to the heat sink. The faces of the heat generating elements on the other side are in direct or indirect contact with the cover. The cover is fixedly screwed to the heat sink at opposite ends in the alignment direction on the outer side of the heat generating elements. The heat generating elements are sandwiched and held between the heat sink and the cover. This allows heat generated by the heat generating elements to be efficiently radiated via the heat sink and allows the heat generating elements to be easily connected to the heat sink.

The present disclosure relates to heat dissipation apparatuses. In an example, a node includes a structural module, a circuit board, a liquid pipe, and a liquid leakage monitoring apparatus. The circuit board is securely mounted on the structural module, and an electronic component including a chip is disposed on the circuit board. The liquid pipe is disposed on the circuit board, and is configured to dissipate heat for the electronic component on the circuit board. The liquid leakage monitoring apparatus includes a drainage pipe sleeved outside the liquid pipe. There is a specific gap between the drainage pipe and the liquid pipe. In response to at least that leakage occurs in the liquid pipe, leaked coolant flows in the drainage pipe.

A power module and a power device are provided. The power device includes two screws, a heat dissipation components and a power module. The power module includes a substrate, a package body and two fixing structures. Each fixing structure includes a first through hole, two second through holes, an annular structure and two sinking structures. When the power module is fixed to the heat dissipation component, each sinking structure is bent toward the heat dissipation component, and each annular structure is fixed to the flat surface of the heat dissipation component by the screws. The heat dissipation surface of the substrate can be flatly attached to the flat surface of the heat dissipation component through the two fixed structures, so that the heat energy generated during the operation of the power module can be transferred out through the heat dissipation component.

A generator control unit (GCU) having thermal control includes a GCU housing having a first side and a second side. A printed wiring board (PWB) is within the GCU housing between the first side and the second side. The PWB includes a component side that faces a first side of the GCU housing. At least one through via is positioned through a thickness of the PWB. At least one boss is positioned on the component side of the PWB. The at least one boss extends from a component of the PWB to the first side of the GCU housing.

An eyewear device has an antenna system having at least one element which contributes to wireless signal transmission, and which is thermally connected to a heat-generating electronic component of the eyewear device to serve as a heat sink for the electronic component. A driven antenna element and/or a plurality of PCB extenders electrically connected to a PCB ground plane can thus be employed for both signal transmission and heat management.

Provided is an aerosol generating apparatus including: a heater configured to generate aerosol by heating a cigarette, the heater including a first electrically conductive heating element formed along a first path on an electrically insulating substrate, a second electrically conductive heating element formed along a second path on the electrically insulating substrate, and a temperature sensor track formed along a third path in a region between the first path and the second path; a battery configured to supply power to the heater; and a controller configured to control the power supplied from the battery to the heater and monitor a temperature sensed using the temperature sensor track.

A method may include coating an electronic module in a tool, where the electronic module has a first sub-module and a second sub-module, where the tool has a first tool part and a second tool part, where the tool has a cavity at least partially formed between the first tool part and the second tool part, and where the first sub-module and the second sub-module are supported on the tool and held in the cavity at a spatially defined distance relative to one another in a contactless manner during the coating process. A tool for performing such method may include a first tool part and a second tool part that form a cavity, where the first tool part has a first molding surface section and at least one first supporting section that extends over the first molding surface section and the second tool part has a second molding surface section and at least one second supporting section that extends over the second molding surface section.

A first circuit board includes a positive output pin and a negative output pin of a power conversion circuit, each of which has a shape projecting from a second main surface. A second circuit board has a positive through via and a negative through via, each of which has a shape extending between a third main surface and a fourth main surface. The second main surface of the first circuit board and the third main surface of the second circuit board are physically in close contact with each other. The positive output pin is inserted through the positive through via to reach the fourth main surface. The negative output pin is inserted through the negative through via in such a manner as to reach the fourth main surface. The load receives a current supplied from the power conversion circuit through the positive output pin and the negative output pin.