A transistor heat dissipation module is adapted for at least one transistor. The transistor heat dissipation module includes a heat dissipation member and an elastic member. The heat dissipation member includes a first wall and a second wall opposite to each other and a first connecting member connected to the first wall and the second wall. An accommodating space is formed between the first wall and the second wall. The transistor is disposed in the accommodating space. The elastic member is disposed in the accommodating space and is located between the at least one transistor and the first wall to press the at least one transistor against the second wall. An assembly method of a transistor heat dissipation module is further provided.

An electrical connector is essentially composed of a pair of half housings opposite to each other in a longitudinal direction to commonly form a receiving cavity for receiving a CPU. Each half housing is equipped with a plurality of contacts with corresponding contacting sections upwardly extending into the receiving cavity for mating with the CPU. A single pick-up cap includes a plate with a plurality of claws adapted to be engaged within locking recesses in exterior sides of the half housings, a plurality of positioning blocks adapted to extend into the receiving cavity so as to cooperate with the claws to sandwich the periphery wall of the housing therebetween in the longitudinal direction for securing the half housings to the pick-up cap. Therefore, both the pair of half housings may be grasped by the single pick-up cap for mounting and soldering to PCB at the same time.

An electronic assembly includes an electronic package connected to a host circuit board. The electronic assembly includes interposer assemblies electrically connected to the electronic package. The electronic assembly includes cable modules coupled to upper separable interface of the interposer assemblies. The electronic assembly includes carrier assemblies configured to be coupled to an upper surface of the electronic package. Each carrier assembly includes a carrier base block and a carrier lid configured to hold at least one interposer assembly and at least one cable module. The carrier assemblies hold the cable modules with the module contacts in electrical connection with upper mating interfaces of the interposer contacts. The carrier assemblies hold lower mating interfaces of the interposer contacts in electrical connection with upper package contacts of the electronic package. The carrier assemblies are separately removable from the electronic package to separate the interposer assemblies from the electronic package.

A temperature control component includes a TEC that includes a top surface and a bottom surface. A thermal conduction layer includes a top surface and a bottom surface. The top surface of the thermal conduction layer is coupled to the bottom surface of the TEC. The bottom surface of the thermal conduction layer includes a planar area. The planar area of the thermal conduction layer is to be positioned above two or more electronic devices of multiple electronic devices of an electronic system to transfer the thermal energy at the two or more electronic devices.

A circuit board assembly for electronic devices includes a circuit board having a first surface and a second surface opposite the first surface, and a heat sink carrier disposed on the first surface of the circuit board. The heat sink carrier includes at least one clamp portion. The assembly also includes a heat sink. The heat sink is positioned in the at least one clamp portion of the heat sink carrier to transfer heat from one or more electronic devices to the heat sink via the heat sink carrier.

An apparatus is described. The apparatus includes a loading frame for mounting a packaged semiconductor chip and a heat sink for the packaged semiconductor chip to a socket. The loading frame is comprised of metal. The loading frame has at least one frame leg where the metal is folded to re-enforce a strength of the frame leg.

In an apparatus for coupling integrated circuits to printed circuit boards, a backing plate with manufactured features on the top surface includes a module lid; a planar structure; a device seated in the planar structure, with the module lid in contact with the top surface of the device; and a backing plate that contains manufactured features on one side. The backing plate is in contact with the planar structure, and a plurality of fastening mechanisms couple together the lid, the device, the planar structure, and the backing plate.

Disclosed is a power conversion device comprising: a case; a switching unit comprising a plurality of switches which are disposed on one side of the case; a transformer disposed on one side of the case; and a clip for fixing the plurality of switches. The clip comprises: a body part which is fixed to the case; and elastic parts which extend from the body part and are for pressing the plurality of switches to the case. The body part comprises a plurality of first through holes into which screws are coupled. And the first through holes are disposed between two adjacent elastic parts.

A latch assembly for latching a heat sink onto a printed circuit board (PCB). The latch assembly includes a clamp having a connector for connecting the latch assembly to the heat sink. A spring is mounted to the clamp for biasing the clamp away from the heat sink. A handle is rotatably connected to the clamp, and a cam extends from the handle. A hook is moveably mounted to the clamp and has a cam surface engaged with the cam. The hook has an engagement portion for engaging the PCB. Rotation of the handle causes (i) rotation of the hook, which causes the engagement portion to engage the PCB, followed by (ii) movement of the cam along the cam surface, which causes translation of the clamp toward the PCB against the bias of the spring, which causes the heat sink to contact an IC for dissipating heat from the IC.

The disclosure provides a retainer which is configured to be mounted on and fix heat dissipation module onto chip platform. The retainer includes pressing portion, first and second latching portions. The first latching portion includes flat portion and flexible curved portion, the flexible curved portion is connected between the pressing portion and the flat portion, long side of the flat portion is substantially perpendicular to a long side of the pressing portion. The second latching portion is connected to the pressing portion. A long side of the second latching portion is substantially perpendicular to the long side of the pressing portion. The first portion and the second latching portion are configured to be detachably engaged at two opposite sides of the chip platform so as to deform the flexible curved portion and utilize the flexible curved portion to enhance a pressing force applied to the heat dissipation module.