An electronic assembly and a heat dissipation assembly thereof. The electronic assembly includes a circuit board and a heat dissipation assembly. The circuit board includes a plate body and a heat source disposed on the plate body. The heat dissipation assembly includes a fin assembly, a mounting plate body, and a heat dissipation pillar. The mounting plate body is fixed to the fin assembly and includes a mounting hole. The heat dissipation pillar is engaged in the mounting hole of the mounting plate body. One end of the heat dissipation pillar is in thermal contact with the fin assembly, and another end of the heat dissipation pillar is in thermal contact with the heat source of the circuit board.

A base of a connector defines an accommodation portion for accommodating a card-type device. The base has holding portions with surfaces directed to the accommodation portion. The holding portions hold held portions of terminals 40. Heat conductive members are provided on the surfaces of the holding portions. The heat conductive members are sandwiched between the card-type device and the holding portions when the card-type device is connected to the connector 10. In this way, heat conductive paths, which include the conductive members, are formed between the card-type device and held portions of the terminals 40.

An electronic load device includes a main board and a load module. The main board has a plurality of first connecting ports. The load module includes a sub board and a heat-dissipating unit. The sub board has a second connecting port and a pin-hole port. The second connecting port is used for detachably connecting one of the plurality of first connecting ports. The pin-hole port is used for connecting a power component. The heat-dissipating unit has a cylindrical body and a plurality of heat-dissipating fins. The cylindrical body is defined with an outer surface and an inner surface opposite to the outer surface. The plurality of heat-dissipating fins is connected with the outer surface. When the power component is connected to the pin-hole port, the power component contacts the inner surface.

A semiconductor device includes a vapor chamber lid for high power applications such as chip-on-wafer-on-substrate (CoWoS) applications using high performance processors (e.g., graphics processing unit (GPU)) and methods of manufacturing the same. The vapor chamber lid provides a thermal solution which enhances the thermal performance of a package with multiple chips. The vapor chamber lid improves hot spot dissipation in high performance chips, for example, at the three-dimensional (3D-IC) packaging level.

Thermal coupling with between an electrical component, such as a CPU, and a heatsink can be provided by a movable heatsink insert separate from the heatsink. This movable heatsink insert can be placed on the electrical component. The heatsink can be thermally coupled to that additional thermal conductor. The heatsink, which is attached to the printed circuit board, is not in direct contact with the electrical component, reducing the likelihood that the heatsink could cause bending of the printed circuit board by pressing down on the electrical component. Further, a spring coupled between the heatsink and the movable heatsink insert can provide further pressure relief such that the heatsink assembly can be attached to an electrical component without applying excessive force to the electrical component.

A semiconductor baseplate is disclosed. Specific implementations of a baseplate may include a planar portion including a plurality of recesses therein, the planar portion may be made of a first material, and a plurality of pegs where each peg of the plurality of pegs may be configured to fit within each recess of the plurality of recesses, the plurality of pegs may be made of a second material, where the first material and the second material may be bonded together.

A heat sink includes a first fin and a second fin. The spacing between the first fin and the second fin may be adjusted by a threaded rod. The threaded rod may include a first portion that is engaged with the first fin and a second portion that is engaged with the second fin. The thread pitch of the first portion and the second portion may differ. For example, the pitch of a first internal thread of the first fin may be smaller than the pitch of a second internal thread of the second fin. The spacing of the heat sink fins may be adjusted based upon the current operating conditions of the electronic device to maintain an optimal temperature of a heat generating device during device operation.

Disclosed herein are integrated circuit (IC) packages with an electronic component having a patterned protective material on a face, as well as related devices and methods. In some embodiments, a computing device may include: an integrated circuit (IC) package with an electronic component having a protective material on the back face of the electronic component, where the protective material is patterned to include an area on the back face of the electronic component that is not covered by the protective material; a circuit board, where the IC package is electrically coupled to the circuit board; and a heat spreader, where the heat spreader is secured to the circuit board and in thermal contact with the area on the back face of the electronic component that is not covered by the protective material.

A circuit board assembly is applied to the field of electronic communications technologies to resolve a prior-art heat dissipation problem of a circuit board. The circuit board assembly combines, on a second circuit board, low-speed signals transmitted between a plurality of I/O modules and an IC chip, and then transmits the combined low-speed signals to the IC chip by using a low-speed cable. A low-speed signal sent by the IC chip to the plurality of I/O modules is extended to a plurality of low-speed signals on the second circuit board, and then the plurality of low-speed signals are separately sent to the plurality of I/O modules. This may be applied to a scenario in which a relatively large quantity of electronic components need to be disposed on a circuit board.

This disclosure relates to a network interface card includes a first interface card. The first interface card includes a first circuit board and a first connector. The first connector is disposed on the first circuit board. The first circuit board includes a plurality of connection terminals with longitudinal axes in different directions from the first connector. The first connector is a board-to-board connector.