The power on wafer assembly can include: a compliant connector, an integrated circuit, a printed circuit board (PCB), a power component, and a set of compliant connectors. The power on wafer assembly can optionally include: a compression element, a cooling system, a set of mechanical clamping components, and a power source. However, the power on wafer assembly can additionally or alternately include any other suitable components.

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 device for cooling a plurality of electrical components, each having a component cooling surface to be cooled, includes a first heat sink, a second heat sink, and a plurality of fasteners. The first heat sink has a first heat-sink cooling surface, and the second heat sink has a second heat-sink cooling surface. The first and second heat-sink cooling surfaces are positioned in a planar arrangement such that the first and second heat-sink cooling surfaces face each other. The first heat-sink cooling surface is configured to receive a first sub-set of the component cooling surfaces of the plurality of electrical components, and the second heat-sink cooling surface is configured to receive a second sub-set of the component cooling surfaces. The fasteners are configured to fasten the first and second heat-sink cooling surfaces to the corresponding component cooling surfaces of the plurality of electrical components to be applied.

Various semiconductor chip packages are disclosed. In one aspect, a semiconductor chip package is provided that includes a package substrate that has a first edge and a second edge opposite to the first edge. A semiconductor chip is mounted on the package substrate. A thermal interface material is positioned on the semiconductor chip. A lid is positioned over the thermal interface material. A spring biasing mechanism is included that is operable to bias the lid away from the package substrate so that the lid, when subjected to a compressive force, can translate toward the package substrate and impart a compressive force on the thermal interface material.

Removing device including: a heat exchanger that is mounted on a platen so that the exchanger lies above and a distance away from an electronic component; a chassis that lies between the electronic component and the platen, and device for fastening the chassis to the platen or to the electronic board; a rigid heat sink that is mounted on the chassis in order to slide perpendicularly to the electronic board and that has a first end making contact with the component and a second end in abutment against a thermally conductive layer that is fastened to the platen in order to elastically return the rigid heat sink into abutment against the electronic component whatever the thickness of the electronic component. Electronic equipment having such a removing device.

A multi integrated circuit (IC) chip package includes multiple IC chips, a carrier, and a lid. The IC chips may be connected to the carrier. Alternatively, each IC chip may be connected to an interposer and multiple interposers may be connected to the carrier. The carrier may be positioned against a carrier deck. The lid may be positioned relative to carrier by aligning one or more alignment features within the lid with one or more respective alignment features of the carrier deck. A compression fixture cover may contact the lid and exert a force toward the carrier deck, the lid be loaded against respective IC chips, and the lid may be loaded against the carrier. While under compression, thermal interface material between respective the lid and respective IC chips and seal band material between the lid and the carrier may be cured.

A flexible heat transfer mechanism is provided for transferring heat from a heat generating component to a heatsink. The heat transfer mechanism may include a pedestal coupled to the heatsink via a heat transfer element. The heat transfer element may be a compliant member that is capable of flexing in a vertical direction such that the pedestal may be vertically displaced relative to the heatsink.

A multi integrated circuit (IC) chip package includes multiple IC chips, a carrier, and a lid. The IC chips may be connected to the carrier. Alternatively, each IC chip may be connected to an interposer and multiple interposers may be connected to the carrier. The carrier may be positioned within a carrier deck. The lid may be positioned relative to carrier by aligning one or more alignment receptacles within the lid with one or more respective alignment protrusions of the carrier deck. A compression fixture cover may contact the lid and exert a force toward the carrier deck, respective lid pedestals may be loaded toward respective IC chips, and an integral lid foot may be loaded toward the carrier. While under compression, thermal interface material between respective lid pedestals and respective IC chips and seal band material between the integral foot and the carrier may be cured.

A chip package structure is provided and includes a PCB, a chip, a package cover, a thermal interface material layer, and a heat sink. The chip is welded to the PCB. The package cover is disposed on the PCB. The chip is packaged in the package cover. The thermal interface material layer covers the chip, and is attached to an inner top surface of the package cover. The heat sink is disposed on the PCB. An assembly space is formed between the heat sink and the PCB. The heat sink includes a contact plate. A lower end face of the contact plate abuts against an outer top surface of the package cover. A projection of the abutting member in a height direction of the chip package structure covers the chip, and is located in a region enclosed by an edge of the outer top surface of the package cover.

A printed wiring board assembly is disclosed that includes a printed wiring board with a first side and a second side opposite first side. Magnet structures are in physical contact with the printed wiring board and a microelectronic device component is coupled to the first side of the printed wiring board. A heat spreader overlies and is in thermal communication with the microelectronic device component, and posts are coupled to the heat spreader and horizontally neighbor the microelectronic device component, where the posts are in magnetic communication with the magnet structures. Related methods and electronic systems are also disclosed.