A locking push pin and methods of using the locking push pin to assemble a heatsink assembly, are described. The locking push pin includes a body lumen extending through a pin body, and several prongs radially outward from the body lumen. Peripheral surfaces of the prongs are separated by a body slot radially outward from the body lumen. The locking push pin includes a pin lock having a branch that extends through the body lumen and into the body slot between the peripheral surfaces. The pin lock advances from an unlocked configuration in which the branch is in the body slot proximal to a distal end of the prongs, allowing the prongs to deflect radially inward, to a locked configuration in which the branch is in the body slot at the distal end of the prongs, blocking deflection of the prongs. Other embodiments are also described and claimed.

A cooling assembly is described. The cooling assembly includes a semiconductor chip package having input/outputs (I/Os) on a first surface and a package lid that is opposite the first surface, the semiconductor chip package has sides between the first surface and the package lid. The cooling assembly includes a structured element. The structured element has a structured surface to nucleate bubbles in a bath of coolant. The structured element has fixturing elements to secure the structured element to at least first and second ones of the sides of the semiconductor chip package. The structured element has a first thermal resistance. The cooling assembly has a thermal interface material between the package lid and the structured element. The thermal interface material has a second thermal resistance that is greater than the first thermal resistance and within an order of magnitude of the first thermal resistance.

The technology relates to a cage configured to removably receive a module. The cage may include a frame comprising a plurality of panels joined to one another, a lever pivotably coupled to the frame, and a heatsink pivotably coupled to the lever. The panels together may extend around a longitudinal recess configured to receive the module therein. The longitudinal recess may define a longitudinal axis thereof. A first one of the panels may have an aperture defined therein in communication with the longitudinal recess. A first end of the lever may extend into the longitudinal recess. The heatsink may be pivotably coupled to a second end of the lever opposite the first end. The heatsink may be movable in a translation direction transverse to the longitudinal axis. The heatsink may be translatable between a first position outside of the longitudinal recess and a second position partially inside the longitudinal recess.

A semiconductor power module is configured in such a way that a protruding portion of a heat sink is inserted into a penetration hole of a jacket, that an end face portion of the protruding portion and a cooling fin are exposed in a flow path, that a front-end portion of the cooling fin abuts on an inner wall surface of the flow path, that a packing is mounted in a groove portion formed between an inner wall portion of the penetration hole and a side wall portion, of the protruding portion of the heat sink, that faces the inner wall portion, that the inner wall portion of the penetration hole and the side wall portion of the protruding portion press the packing in the radial direction thereof, that a spring member presses the front-end portion of the cooling fin to the inner wall surface of the flow path.

A microprocessor carrier comprising a lever having an elongate arm and a wedge structure extending from one end of the elongate arm, and a frame comprising and a fulcrum structure to receive the lever and a microprocessor. The fulcrum structure is to couple the lever to the frame.

A microprocessor carrier, comprising a frame comprising a metal. The first frame surrounds an aperture for receiving a microprocessor package. At least one hinge assembly is on a first frame edge, and at least one latch assembly is on a second frame edge. One or more alignment tabs coupled to the frame. The one or more alignment tabs extend orthogonally from at least one frame edge. The alignment tabs are to align the microprocessor package with a microprocessor socket. The hinge assembly and the latch assembly are to engage with a microprocessor loading mechanism coupled to a printed circuit board.

Systems and methods are disclosed relating to welding-type power supplies. In some examples, the power supplies may have no vents, which may help prevent environmental contaminants from entering the power supplies. Instead, the power supplies include one or more thermal interfaces configured to conduct heat generated by internal circuitry of the power supply from the interior of the power supply to an exterior of the power supply. Additionally, the thermal interface(s) may be configured for attachment to one or more exterior heat dissipating devices.

An apparatus is described. The apparatus includes a semiconductor chip package assembly having a spring element to be coupled between a first mechanical element and a second mechanical element to apply a loading force that pulls the first and second mechanical elements toward each other in the assembly's nominal assembled state. The first and second elements to support a cooling mass, the assembly further comprising a dampener that is coupled to at least one of the first and second mechanical elements to reduce oscillation amplitude of the cooling mass.

The invention provides a heat sink. The heat sink is configured to be in thermal contact with a heat source. The heat sink includes a base portion, a plurality of fin portions, and a wall portion. The base portion includes a thermal contact surface and a rear surface. The thermal contact surface is configured to be in thermal contact with the heat source, and the rear surface faces away from the thermal contact surface. The fin portions protrude from the rear surface of the base portion. The wall portion protrudes from the rear surface of the base portion and surrounds the fin portions. In addition, the invention also provides an electronic assembly including the heat sink.

In one embodiment, a semiconductor package may be formed having a first side and a second side that is substantially opposite to the first side. An embodiment may include forming an attachment clip extending substantially laterally between the first and second sides wherein the attachment clip is positioned near a distal end of the first and second sides. An embodiment may also include forming the attachment clip to have a flexible main portion that can bend away from a plane of the main portion toward a bottom side of the semiconductor package.