A display device includes a display panel, a printed circuit board attached to the display panel and including a ground potential supply terminal, a circuit, and a wiring pattern electrically coupling the ground potential supply terminal and the circuit, and a housing that contacts a coupling place provided to the wiring pattern and is attached to the printed circuit board through the coupling place. The wiring pattern includes a terminal wiring pattern electrically coupled with the ground potential supply terminal, a circuit wiring pattern branched from a branch part at a predetermined position on the terminal wiring pattern and electrically coupled with the circuit, and a housing wiring pattern branched from the branch part of the terminal wiring pattern and electrically coupled with the coupling place, and the circuit wiring pattern and the housing wiring pattern are uncoupled with each other at any place other than the branch part.

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 video transcoding card includes a first transcoding assembly and a second transcoding assembly. The first transcoding assembly includes a first circuit board, first transcoding boards, and a first main electrical connector. The first transcoding boards and the first main electrical connector are disposed on the first circuit board and are electrically connected to the first circuit board. The second transcoding assembly includes a second circuit board, second transcoding boards and a second main electrical connector. The second transcoding boards and the second main electrical connector are disposed on the second circuit board and are electrically connected to the second circuit board. The first main electrical connector and the second main electrical connector are connected to each other, and the second transcoding boards are electrically connected to the first circuit board via the second circuit board, the second main electrical connector, and the first main electrical connector.

The casing of an electronic control device includes a casing-side contact surface in contact with the end of a printed-circuit board. A cover includes a cover-side contact surface holding the end of the printed-circuit board together with the casing-side contact surface by being in contact with the end of the printed-circuit board. In the printed-circuit board, a held portion held between the casing-side contact surface and the cover-side contact surface is provided with a through-hole via.

This application discloses a board, an electronic device, and a manufacturing method, and pertains to the field of bare die package technologies. The board includes a PCB assembly, a bare die, a reinforcing frame, a heat sink, and fasteners. Both the bare die and the reinforcing frame are located on a surface of the PCB assembly, the bare die is located in the reinforcing frame, and the reinforcing frame is fixedly connected to the PCB assembly by using the fastener. The heat sink is located on a surface of the bare die that is away from the PCB assembly, and the heat sink is fixedly connected to the reinforcing frame by using the fastener.

A printed circuit board comprises N power switching cells operating in parallel and respectively comprising a transistor leg, at least one decoupling capacitor and a gate driver circuit. Each transistor leg comprises respective first and second transistors in series, a drain of the first transistor being connected to a positive DC line, a source of the second transistor being connected to a negative DC line, a source of the first transistor being connected to a drain of the second through a connection middle-point connected to an output terminal. Each gate driver circuit controls respective switching ON and OFF of the corresponding first and second transistors. The N transistor legs of the corresponding N power switching cells are positioned to substantially form a convex polygon having N edges of substantially the same length, each one of the N transistor legs being positioned along one of the edges of the convex polygon.

Aspects of the disclosure provide a printed circuit board (PCB) system that includes an integrated circuit (IC) package, a first PCB and a PCB module. The IC package has a package substrate and an IC chip that is coupled to a top surface of the package substrate. The first PCB is configured to electrically couple with first contact structures that are disposed on a bottom surface of the package substrate. The PCB module includes a second PCB and one or more electronic components electrically coupled to the second PCB. The PCB module is configured to electrically couple with second contact structures that are disposed on the top surface of the package substrate.

An electronic assembly 52 includes a plurality of circuit boards 70, 74, 78 each comprising engagement grooves 84 spaced around an outer wall. The assembly includes a plurality of spacers 72, 76 with alignment elements. The alignment elements comprise a first tab 92 and a first tab receiver 93 extending in a first axial direction. The alignment elements further comprising a second tab 90 extending in a second axial direction opposite the first and a second tab receiver 91 extending in the second axial direction. A first spacer 72 is disposed between a first circuit board 70 and a second circuit board 74. The first tab 92 of the first spacer 72 is disposed within a first engagement groove of the first circuit board 70. The second circuit board 74 is disposed between the first spacer 72 and a second spacer 76. A second tab 90 of the first spacer 72 is received in a second engagement groove 84 of the second circuit board 74 and a first tab receiver 93 of the second spacer 76.

An electric component includes a printed circuit board with each of a pair of surfaces serving as a component mounting surface. The component mounting surface has a predetermined region on which electronic components are coated with a resin. A predetermined one of the electronic components in the region is not covered with the resin at a portion above a predetermined height from the component mounting surface.

A support structure supports a component mounted on a mounting surface of a structure by pressing the component to the mounting surface side and includes a first support tool and a second support tool used so that the component is pressed to the mounting surface side and supported and a fixing portion provided on the structure and fixing the first support tool and the second support tool. The first support tool and the second support tool are fixed to the same fixing portion.