Examples of card fasteners and assemblies for fastening cards to printed circuit boards are discussed. A card fastener comprises a frame comprising a first arm, a second arm, and an intermediate portion joining the first arm and the second arm. A compressive pad is attached to the intermediate portion. The first arm and second arm are to couple to hooks on a printed circuit board of a device and the compressive pad is to come in contact with the card.

A guiding device includes a first telescopic member, a second telescopic member, and an elastic member. The first telescopic member includes a main body with a sliding cavity. The second telescopic member includes a connecting portion and a guiding portion connected to the connecting portion. The guiding portion is slidably inserted into the sliding cavity. Opposite ends of the elastic member are respectively connected to the connecting portion and the main body. The elastic member pushes the main body in a direction away from the connecting portion. The disclosure also provides a mainboard connection structure having the above guiding device.

A cell-contacting system for a battery module having an array of a plurality of battery cells. Cell connectors connect the cell terminals of the battery cells. The signal lines of a printed circuit board connect a signal source of one of the cell connectors to a signal management circuit or a connection interface. A plastics material carrier plate fits onto the battery cell array and has a first receiving region for the printed circuit board and a plurality of second receiving regions for one each of the plurality of cell connectors. The carrier plate has a base plate and frame elements for receiving the printed circuit board and the cell connectors. Snap-action hooks on the frame elements allow the printed circuit board or the cell connectors to be snap-fit into the corresponding receiving regions.

Disclosed is a display unit provided with a display control printed circuit board with a circuit configured to generate a display signal for display by a display panel and a fixing metal plate for securing the display control printed circuit board. The display control printed circuit board is provided with identification information reading means for reading identification information of the display panel, a memory stored with set values for generating display signals corresponding to the sizes of a plurality of display panels, and a display controller configured to generate the display signals. The fixing metal plate comprises one or more members electrically connected to the display control printed circuit board and configured to transmit the identification information of the display unit to the display control printed circuit board. The identification information reading means reads a set value for the display panel from the memory, based on the identification information of the display panel derived from the one or more electrically connected members, and sets the set values in the display controller configured to generate the display signals.

The disclosure relates to an electronic component that includes a printed circuit board with two opposite flat sides and a plurality of electronic components, and a base plate. A number of the electronic components are each fixed on and electrically conductively connected to a rear flat side of the printed circuit board and a further number of the electronic components are each fixed on and electrically conductively connected to a front flat side of the printed circuit board. The base plate has at least one first cutout for receiving electronic components that are arranged on the rear flat side of the printed circuit board. The disclosure also relates to a method for producing an electronic component of this kind.

Heat transfer devices and systems for thermally coupling electrical components to a heatsink can comprise one or more all-metal heat transfer device(s) thermally coupling at least one electrical component to a heatsink. A heat transfer device can comprise a metal cup attached to a metal heatsink, and a metal piston and a compliant device disposed in the cup. The piston is forcible to a secured first position, upon reflowing solder, while compressing the compliant device. Upon reflowing solder again, the compliant device causes the piston to bias and attach to the electrical component to provide an all-metal thermal path and absorb assembly tolerances to avoid using thermal gap fillers. A method is provided for thermally coupling a heatsink to a plurality of electrical components via a plurality of all-metal, expandable heat transfer devices.

The invention is related to an electrical circuitry assembly as well as a method for manufacturing such an electrical circuitry assembly, wherein the assembly basically but not exclusively comprising of an electrically conductive metal plate and a circuit including a conductive layer and wherein both the metal plate and the circuit shall be electrically connected to each other.

The disclosure provides a power supply including a high heat-dissipation circuit board assembly system in which a rack is installed on a circuit board so as to be connected to a transformer. Heat produced when electronic components installed on the circuit board are actuated may be conducted and dissipated thereby. The efficiency and the heat conductivity effect of the power supply may be further enhanced by distributing the amount and the flowing direction of the current from the transformer.

A panel device including a substrate, a conductor pad, a turning wire, and a circuit board is provided. The substrate has a first surface and a second surface connected to the first surface while a normal direction of the second surface is different from a normal direction of the first surface. The conductor pad is disposed on the first surface of the substrate. The turning wire is disposed on the substrate and extends from the first surface to the second surface. The turning wire includes a wiring layer in contact with the conductor pad and a wire covering layer covering the wiring layer. The circuit board is bonded to and electrically connected to the wire covering layer. A manufacturing method of a panel device is also provided herein.

An interconnection substrate having a barcode includes a core layer, an interconnection layer over a first surface of the core layer, an insulating layer to cover the interconnection layer, and one or more additional interconnection layers over the insulating layer, wherein the barcode includes cells arranged at spaced intervals, and a cell pattern is made by forming penetrating holes through the core layer in some of the cells but not in remaining ones of the cells, wherein the penetrating holes are filled with resin, and an end face of the resin is exposed on the same side as the first surface such that the interconnection layer is situated in a surrounding area of the end face but not over the end face, and wherein a number of interconnection layers over the end face is smaller than a number of interconnection layers in the surrounding area of the end face.