An immersion cooling assembly comprises at least one primary heat-generating electronic component and a flow-through cooling module mounted near the at least one primary heat-generating component. The flow-through cooling module comprises at least one inlet conduit to accept an inflow of pressurized dielectric coolant, a fluid chamber through which fluid flows to provide targeted, direct cooling to a heat-generating component, and exit passageways to facilitate flow-through of the dielectric coolant into a surrounding immersion bath for cooling of other components. As it flows out of the cooling module and over the heat-generating component, the coolant fluid absorbs heat from the heat-generating electronic component. In certain embodiments, the assembly may also comprise at least one periphery heat-generating electronic component, which may also be cooled by the dielectric coolant as it exits the vicinity of the flow-through cooling module. The cooling module may include impingement nozzles to accelerate and direct the flow of coolant fluid toward the high-heat-generating electronic component.

A positioning fixture including a shielding member and a driving member is provided. The shielding member includes a sliding part slidably connected to a functional module, a guiding part, and a shielding part. The sliding part and the shielding part respectively extend from two opposite ends of the guiding part. The driving member is movably disposed on the functional module corresponding to the shielding member. The driving member includes a base part, a driving part that contacts the guiding part, and a pillar part, which protrudes from the base part and is adapted to pass through the guiding groove. When the functional module is positioned on the circuit board, the base part of the driving member is pushed by the electronic component, and the guiding part is pushed by the driving part, so that the shielding member slides and the shielding part shields a screw hole of the circuit board.

A method for manufacturing a fin-integrated semiconductor module includes: clamping a fin-integrated heat-dissipation base using a level different jig while making the heat-dissipation base vary in height; and soldering a semiconductor assembly onto the heat-dissipation base. A semiconductor module includes a fin-integrated heat-dissipation base and a semiconductor assembly provided on the heat-dissipation base. A bending width of the heat-dissipation base is 200 μm or less.

There is described a spray chamber for cooling a computer processor on a circuit board. The spray chamber comprises: a wall assembly for sealable mounting on an exposed cooling surface of the computer processor defining an enclosure having a top opening and a bottom opening which opens on the top surface of the computer processor; and a lid for covering the top opening of the wall assembly in a sealable manner, the lid having a nozzle which sprays coolant that impinges on the exposed cooling surface of the computer processor.

An integrated circuit (IC) socket comprising a housing with a land side, an opposing die side, and sidewalls around a perimeter of the housing. The housing comprises a first dielectric. A plurality of socket pins extends from the land side of the housing through socket pin holes in the housing over the die side of the housing. A second dielectric is within the interstitial regions between the socket pins and sidewalls of the socket pin holes. A frame structure extends around at least a portion of the perimeter of the housing, and a mesh structure is embedded within the first dielectric. The mesh structure has plurality of mesh filaments extending between the plurality of socket pin holes and coupled to the frame structure.

The invention relates to a module housing made of plastic, in particular a thermosetting polymer, with an embedded cooling element and at least one screw sleeve, which has a collar with an exposed mounting surface with which the module housing can be mounted on a support functioning as an external heat sink. The cooling element and the at least one screw sleeve form a monolithic element with which heat can be conducted from the cooling element to the support via at least the mounting surface.

A system for cooling computer hardware includes a first heat exchanger and a pump. The first heat exchanger includes a computer hardware contact surface configured to be in thermal contact with the computer hardware on a first side and to be in thermal contact with a cooling liquid on a second side. The first heat exchanger also includes a liquid chamber having a pump interface with at least one chamber inlet and at least one chamber outlet. The pump includes a chamber interface with at least one pump outlet and at least one pump inlet. The pump is configured to: detachably connect at the chamber interface to the pump interface, and drive the cooling liquid from a second heat exchanger to the at least one pump outlet and from the at least one a pump inlet to the second heat exchanger.

A system for cooling computer hardware includes a heat exchanger having a computer hardware contact surface configured to be in thermal contact with the computer hardware on a first side and to be in thermal contact with a cooling liquid on a second side, the second side being opposite to the first side. The system also includes a bracket configured to removably clamp the heat exchangerto the computer hardware.

A semiconductor device includes semiconductor modules disposed on a support member via a cooling plate; and a metal plate which supports a control board for controlling the semiconductor modules, wherein the metal plate, being supported by the support member, covers the semiconductor modules, and also fixes the control board opposite the installation surfaces of the semiconductor modules.

Methods, systems, apparatus, and articles of manufacture to control load distribution of integrated circuit packages are disclosed. An example apparatus includes a heatsink, a base of the heatsink to be thermally coupled to a semiconductor device, and a rigid plate to be coupled to the semiconductor device and the base of the heatsink, the rigid plate stiffer than the base, the rigid plate distinct from a bolster plate to which the heatsink is to be coupled.