A heat sink component can include a body including a thermally conductive material that is electrically non-conductive, a lower conductive layer formed over a bottom surface of the body and electrically connected with the ground plane layer, and an upper conductive layer formed over a top surface of the body. The heat sink component can have a length in an X-direction that is parallel with the top surface of the body and a thickness in a direction perpendicular to the top surface. A ratio of the length to the thickness can be greater than about 7.

An illustrative example embodiment of an electronic device includes an integrated circuit component having a plurality of solder balls on one side. The substrate includes a first side adjacent the one side of the integrated circuit component. The substrate includes a plurality of openings. At least some of those openings are aligned with the solder balls. A cooling plate is situated toward a second side of the substrate. A thermally conductive material within the plurality of openings is thermally coupled with the cooling plate. At least some of the thermally conductive material is thermally coupled with the solder balls.

Provided is an electric power converter, including: a casing; a heat radiating plate having a first main surface and a second main surface; and a substrate which is fixed to the main surface and to which a heat generating component is mounted, wherein the casing has an inner wall surface in which a first tapered portion is formed, wherein the heat radiating plate includes a second tapered portion which is connected to the first tapered portion in a heat exchangeable manner and slid with respect to the first tapered portion, wherein the heat radiating plate is configured to be displaced in a first direction with respect to the casing by the second tapered portion being slid with respect to the first tapered portion, and wherein the heat generating component is connected to the casing in a heat exchangeable manner by the heat radiating plate being displaced in the first direction.

A module is provided for housing electronic devices and a liquid coolant. The module comprises: a housing defining a sealable internal volume for containing the electronic devices and the liquid coolant, the sealable internal volume having a base; a substrate in the sealable internal volume approximately parallel to the base, one of the electronic devices being mounted on a side of the substrate proximal the base; and a heat sink device, comprising a receptacle part defining an internal volume that is arranged to receive the liquid coolant and accumulate the liquid coolant therein. The heat sink is mounted such that the one of the electronic devices or a component that is thermally conductively coupled to the one of the electronic devices is at least partially within the internal volume.

A heat transfer member-equipped substrate includes a heat transfer member installed in a through hole of a substrate; a heat generating component; and a solder portion soldering the heat generating component to the heat transfer member, a nickel base plating formed on the heat transfer member, and the solder portion bonded to the nickel base plating where a gold plating that suppresses oxidization of the nickel base plating is blended into the solder portion. The heat transfer member includes a first and a second heat transfer portion bonded to each other, the first heat transfer portion made of a first metal, the second heat transfer portion made of a second metal formed on at least a portion of a surface of the second heat transfer portion, and the second heat transfer portion being a plate shape that protrudes from a circumference of the first heat transfer portion.

The heatsink cooling arrangement, fitted to cool a semiconductor component, is transferring heat to a backplate heatsink and secures a mechanical stabile assembly of PCBA, encapsulation, heatsink cooling arrangement to a backplate heatsink, which is fast and easy to assemble with usage of few- or no tools.

A heat dissipation structure includes a heat sink, a first thermal interface material, a second thermal interface material, a circuit board and a circuit element. The first thermal interface material is connected to the heat sink and has fluidity. The second thermal interface material is connected to the first thermal interface material and has no fluidity. The circuit board is connected to the second thermal interface material and has an opening, a top board surface and a bottom board surface. The circuit element includes a convex portion and a base portion. The convex portion has a top convex surface and is disposed in the opening. The base portion is connected to the convex portion and the bottom board surface. The second thermal interface material is connected to the top board surface and the top convex surface.

A driving device includes an electric motor, a rotating shaft, a motor housing, a printed circuit board, an electric power converting circuit, a rear frame end working as a heat radiating member, gel working as a heat transfer member, multiple mounted parts and so on. The heat radiating member is located on a side of the printed circuit board and facing a motor-side surface of the printed circuit board, to which multiple switching elements are mounted. The gel is plastically deformed and adhered to the switching elements and the heat radiating member for transferring heat of the switching elements to the heat radiating member. At least one of the mounted parts is mounted to the printed circuit board and located at a position between a through-hole opposing area and one of the switching elements, which is located at a position closest to a rotational angle sensor mounted to the printed circuit board in the through-hole opposing area.

An integrated power control assembly mounted on an axial end of a three-phase motor includes a substrate, two input busbars each of positive and negative polarities alternatively spaced apart on the substrate, a plurality of sets of paired devices, and three output busbars corresponding to the three phases of the motor, wherein a set of paired devices includes a switching semiconductor and a diode. An inner input busbar has edges adjacent to an inner input busbar of opposite polarity and an outer input busbar of opposite polarity and configured to have at least twice as many devices as the outer input busbars. One or more sets of paired devices are disposed axially on outer input busbars and on inner input busbars along the edges. An individual output busbar is disposed over and electrically coupled to one or more sets of paired devices disposed on adjacent input busbars of opposite polarity.

Provided is a MOSFET device for use with a printed circuit board (PCB) of a battery management system (BMS), the device including a semiconductor body; a metal conductor extending outwardly from a side of the semiconductor body; a plurality of power pins extending outwardly from at least one side of the semiconductor body, the power pins having tips bent downwardly; a gate pin extending outwardly from at least one side of the semiconductor body, wherein the tip of the gate pin is raised or elevated relative to the tips of the power pins so as to avoid electrical contact with the one of the spaced apart copper plates, and wherein the tip of the gate pin is connected to a circuit of the battery management system (BMS).