A chip module includes a circuit board (2), a slot (21) disposed on a surface of one side of the circuit board (2), a lidless packaged chip (5), a heat radiator (4), and a substrate fixing assembly (6). The lidless packaged chip (5) includes a substrate (51) and a die (52) packaged on the substrate (51). The slot (21) is electrically connected to the circuit board (2), the lidless packaged chip (5) has a connecting part on one side of the substrate (51) facing away from the die (52), and the connecting part is inserted into the slot (21). The heat radiator (4) is press-fitted on one side of the die (52) facing away from the circuit board (2). The substrate fixing assembly (6) is press-fitted at a periphery of one side of the substrate (51) facing away from the circuit board (2) and avoids the die (52).

The present disclosure relates to a surface-mounted heat sink and a power module using the same. The power module includes a circuit board, a magnetic element and at least one power device. The magnetic element is disposed at an upper side of the circuit board, the at least one power device is disposed on a surface of the circuit board and located between the magnetic element and a lower side of the circuit board. The surface-mounted heat sink is disposed on the surface of the circuit board and adjacent to the at least one power device. A top surface disposed on one side of the magnetic element and the surface of the circuit board form a limiting height, the surface-mounted heat sink has a first height formed between a sucked surface and a surface-mounted surface thereof, and the limiting height is greater than or equal to the first height.

Heat-rejecting media configured to thermally couple to a heat-generating component of an information handling resource may include a source, a sink, and a thermally-conductive strip coupled between the source and the sink. The source may include a first flexible and thermally-conductive skin surrounding a first cavity comprising a first solid foam, such that mechanical compression by components of the information handling resource provides mechanical pressure for thermally coupling the source to the heat-generating component. The sink may include a second flexible and thermally-conductive skin surrounding a second cavity comprising a second solid foam, such that mechanical compression by components of the information handling resource provides mechanical pressure for thermally coupling the sink to a component of the information handling resource exposed externally to the information handling resource

An integrated circuit package may be formed having a heat transfer fluid chamber, wherein the heat transfer fluid chamber may be positioned to allow a heat transfer fluid to directly contact an integrated circuit device within the integrated circuit package. In one embodiment, a first surface of the integrated circuit device may be electrically attached to a first substrate. The first substrate may then may be electrically attached to a second substrate, such that the integrated circuit device is between the first substrate and the second substrate. The second substrate may include a cavity, wherein the heat transfer fluid chamber may be formed between a second surface of the integrated circuit device and the cavity of the second substrate. Thus, at least a portion of a second surface of the integrated circuit device is exposed to the heat transfer fluid which flows into the heat transfer fluid chamber.

An LED lamp having a metal PCB bent polyhedrally and a method for manufacturing the LED lamp is provided, where a base constituting the metal PCB has a rectangular or geometric shape and is configured to have a plurality of base stepped grooves formed spaced apart from each other on the underside thereof in such a manner as to be bent upward or downward from the base to form reflection surfaces continuously, so that at the time when both ends of the base come into contact with the plane, the base has a geometric shape in which the base is located in space through the reflection surfaces continuously arranged.

An integrated antenna assembly includes one or more antenna elements, one or more electronics components, and one or both of a static discharge element disposed between the antenna element(s) and the electronics component(s) and/or one or more thermal dissipators.

An electronic device includes a system board, a power module and a conductive part. The system board includes a first surface and a second surface opposite to each other. The power module is disposed on the second surface and provides power to the semiconductor device through the system board. The conductive part is disposed on a first side of the power module adjacent to the second surface, wherein the conductive part is electrically connected with the and the system board, wherein the power is transmitted between the and the semiconductor device through the conductive part. The power module includes at least one switch circuit and a magnetic core assembly. The at least one switch circuit disposed on a second side of the power module away from the conductive part. The magnetic core assembly is arranged between the switch circuit and the conductive part.

An example heat transfer apparatus includes a first heatsink, having a first thermal resistance, to remove heat from a first component, a second heatsink, having a second thermal resistance different from the first thermal resistance, to remove heat from a second component, and a mounting structure supporting the first heatsink to couple the first heatsink to the first component. The second heatsink is supported by the first heatsink to couple the second heatsink to the second component.

A cell balancing module according to an embodiment of the present invention comprises: a main board on which a plurality of cell balancing resistors are mounted; at least one sub-board on which a plurality of cell balancing resistors are mounted and which is formed above the main board while being spaced a predetermined distance apart therefrom; and at least one connector which supports the sub-board to be spaced apart from the main board and electrically connects the sub-board to the main board.

An electrical connector assembly includes: a printed circuit board; an electrical connector seated upon the printed circuit board; an electronic package coupled to the electrical connector; a frame structure affixed to the printed circuit board; a metallic securing seat affixed to the frame structure and having plural securing posts; a heat sink positioned upon the electronic package and having plural through holes aligned with the securing posts; plural fasteners each extending through a corresponding through hole to engage a corresponding securing post and plural springs each compressed between an associated fastener and the heat sink; and a retention member mounted to a corresponding securing post for engaging the heat sink, wherein the retention member has a mounting part and a latching part pivoted to the mounting part.