A resin composition including an inorganic filler (B) having an aluminosilicate (A) having a silicon atom content of from 9 to 23% by mass, an aluminum atom content of from 21 to 43% by mass, and an average particle diameter (D50) of from 0.5 to 10 m; and any one or more thermosetting compounds selected from the group consisting of an epoxy resin (C), a cyanate compound (D), a maleimide compound (E), a phenolic resin (F), an acrylic resin (G), a polyamide resin (H), a polyamideimide resin (I), and a thermosetting polyimide resin (J), wherein a content of the inorganic filler (B) is from 250 to 800 parts by mass based on 100 parts by mass of resin solid content.

A control board for a power conversion device, the control board including a board body that is a multilayer board; a first circuit mounted on a first surface of the board body and including a heat generator; a second circuit mounted on the first surface of the board body, the second circuit using a voltage different from a voltage of the first circuit; an insulation region formed on the first surface of the board body, the insulation region performing insulation between the first circuit and the second circuit; and a pattern of a thermal conductive material formed on an internal layer of the board body, extending in a region overlapping with the insulation region as seen from a direction orthogonal to the first surface of the board body, and thermally connected to the heat generator.

Provided are a heat-radiating adhesive member, a heat-radiating sheet using the heat-radiating adhesive member, and an electronic apparatus having the heat-radiating sheet. The heat-radiating adhesive member includes: an adhesive layer; first thermally conductive fillers that are dispersed inside the adhesive layer and spreads heat generated from a heat-generating component of an electronic apparatus in a horizontal direction of the adhesive layer; and second thermally conductive fillers that are dispersed inside the adhesive layer and transfer the heat generated from the heat-generating component of the electronic apparatus to the first thermally conductive fillers.

A thermal management system and method for electronic devices is provided. The system includes an electronic device, a heat sink, and a thermally conducting and electrically insulating thermal bridge that is interposed between the electronic device and the heat sink. The thermal bridge thermally couples the electronic device to the heat sink and electrically isolates the electronic device from the heat sink. The electronic device, the heat sink, and the thermal bridge are mounted on a same planar surface of a printed circuit board.

A wiring board includes a heat dissipation plate, a heat-conductive adhesive layer, an insulating layer, a thermal via, a heat dissipation metal terminal, and electrodes. The heat-conductive adhesive layer is disposed on the heat dissipation plate. The insulating layer is disposed on the heat-conductive adhesive layer. The insulating layer is formed with an opening portion. The thermal via is disposed in the opening portion of the insulating layer. The heat dissipation metal terminal is disposed on the thermal via and electrically connected to the heat dissipation plate. The electrodes are disposed on the insulating layer. The electrodes are to be connected to an electronic component.

The invention relates to a circuit board (1a, 1b, 1c), particularly for a power-electronic module (2), comprising an electrically-conductive substrate (3) which consists, at least partially and preferably entirely, of aluminium and/or an aluminium alloy. On at least one surface (3a, 3b) of the electrically-conductive substrate (3), at least one conductor surface (4a, 4b) is arranged in the form of an electrically-conductive layer applied preferably using a printing method and more preferably using a screen-printing method, said conductor surface (4a, 4b) being in direct electrical contact with the electrically-conductive substrate (3).

The invention relates to a circuit board, particularly for a power-electronic module, comprising an electrically-conductive substrate which consists, at least partially and preferably entirely, of aluminium and/or an aluminium alloy. On at least one surface of the electrically-conductive substrate, at least one conductor surface is arranged in the form of an electrically-conductive layer applied preferably using a printing method and more preferably using a screen-printing method, said conductor surface being in direct electrical contact with the electrically-conductive substrate.

Circuit arrangement for vehicles with at least one semiconductor element 30 and at least one first metal carrier plate 2a and a metal circuit board 2b. A multifaceted scope of application is provided if the carrier plate 2a is electrically insulated from the circuit board 2b and the carrier plate 2a is electrically linked with at least one of the circuit boards 2b by means of at least one semiconductor device 30 so that the carrier plate 2a and the circuit board 2b form an electrical three-pole.

A printed wiring board has thereon an electronic component having a heat radiation pad, and an electrolytic capacitor provided for the electronic component. The printed wiring board further has thereon another electronic component having another heat radiation pad and exhibiting a higher heat value than that of the electronic component, and another electrolytic capacitor provided for the other electronic component. The heat radiation pad of the electronic component, a ground terminal of the electrolytic capacitor, the other heat radiation pad for the other electronic component, and another ground terminal of the other electrolytic capacitor are connected by using a ground conductor. In the ground conductor, a thermal resistance between the other heat radiation pad and other ground terminal is lower than the thermal resistance between the heat radiation pad and the ground terminal.

A printed circuit board and a method of manufacturing the same are provided. The printed circuit board may include a core layer, a metal layer disposed on the core layer, and a heat dissipation unit disposed to pass through the core layer in across a thickness of the core layer.