A battery connection module includes a carrying tray, a plurality of busbars and a flexible circuit board. The plurality of busbars are provided on the carrying tray. The flexible circuit board is provided on the carrying tray, the plurality of busbars is adjacent to the flexible circuit board, and the busbar has a notch which is formed to a side toward the flexible circuit board and a notch side plate portion which is positioned alongside the notch, the flexible circuit board has a bending arm which integrally extend out from the flexible circuit board, the bending arm is positioned in the notch of the busbar and a tip of the bending arm is electrically connected to the busbar. In some embodiments, a battery connection module further includes an output connection port provided to the carrying tray. In some embodiments, a battery connection module further includes a connector provided to the carrying tray.

Lighting device for a motor vehicle including a light source and/or an optical part. A substrate including electrical tracks, the light source and/or optical part being fastened to the substrate, and a part forming an electrical ground for the electrical tracks. The substrate includes a cut-out forming a tab, electrical tracks of the substrate extending onto the tab, at least one of the tracks on the tab making electrical contact with the ground-forming part.

A sensor device is provided for measuring current in an electrical circuit of a PCB, including a coaxial connector mounted on a tab in the PCB having an inner conductor and a concentric outer conductor, where the tab is formed by a gap through the PCB along a portion of a perimeter surrounding the coaxial connector; a sidewall conductor formed on sidewalls of the tab and connected to ground plane; and resistors mounted on the PCB and arranged along the portion of the perimeter surrounding the coaxial connector, each resistor being connected between the inner conductor and the sidewall conductor. Current from the electrical circuit flows in a first direction through the ground plane creating a first magnetic field, and flows in a second direction between the sidewall conductor and the inner conductor through the resistors creating a second magnetic field, where the first and second magnetic field partially cancel.

A control module of an appliance is provided. The control module includes a housing having a film integrally molded onto an outer surface of the housing. The film includes conductive ink embedded in the film. A header on the film is in electrical communication with the conductive ink embedded in the film. The control module also includes a printed circuit board mounted within the housing proximate an inner surface of the housing. The film is connected to the printed circuit board via the header. With this connection, the printed circuit board is in operative communication with the conductive ink embedded in the film.

A cable connector module includes a cable card assembly including a circuit card, cables terminated to the circuit card, and a cable holder coupled to the circuit card and holding the cables relative to the circuit card. The cables include cable conductors electrically connected to corresponding cable contacts of the circuit card. The cable holder holds each of the contacts and includes a connecting tab coupled to the circuit card. The circuit card includes front and rear retaining tabs. The cable connector module includes a connector shell having a cavity that receives the cable card assembly. The connector shell includes a front retainer at the front receiving the front retaining tab to hold the front of the circuit card relative to the connector shell. The connector shell includes a rear retainer at the rear receiving the rear retaining tab to hold the rear of the circuit card relative to the connector shell.

Provided are interconnects for interconnecting a set of battery cells, assemblies comprising these interconnects, methods of forming such interconnects, and methods of forming such assemblies. An interconnect includes a conductor comprising two portions electrically isolated from each other. At least one portion may include two contacts for connecting to battery cells and a fuse forming an electrical connection between these two contacts. The interconnect may also include an insulator adhered to the conductor and mechanically supporting the two portions of the conductor. The insulator may include an opening such that the fuse overlaps with this opening, and the opening does not interfere with the operation of the fuse. In some embodiments, the fuse may not directly interface with any other structures. Furthermore, the interconnect may include a temporary substrate adhered to the insulator such that the insulator is disposed between the temporary substrate and the conductor.

This application provides a printed circuit board assembly and an electronic device. The printed circuit board assembly includes: a printed circuit board, where the printed circuit board includes a functional network, and the functional network is configured to provide an electrical function; a conductive part, where the conductive part is connected to the printed circuit board and is electrically connected in parallel to the functional network; and a cover-shaped structure, where the cover-shaped structure covers the conductive part and is connected to the printed circuit board, and the cover-shaped structure is configured to prevent the conductive part located in the cover-shaped structure from contacting a conductor outside the cover-shaped structure. The foregoing technical solutions can reduce impedance of a circuit board, improve a current utilization, and further improve mechanical reliability of the circuit board.

A wiring substrate comprises a first substrate, a second substrate which includes a frame body located on the outer circumferential edge of the first substrate, at least two connecting parts connected to the inner circumferential part of the frame body, and a support body connecting the two connecting parts to each other, and a third substrate located on a surface of the second substrate opposite the first substrate. The support body includes a direction changing part between the two connecting parts and does not include an annular structure where the direction changing part is included on the circumference.

A flexible electronic foil (1,1′,1″) comprising a flexible substrate (2) and at least one electrically conducive portion (3) arranged to the substrate (2). The foil (1,1′,1″) comprises mechanical fastening means (6,6′,7) for mechanical fastening of the electronic foil (1,1′,1″), the mechanical fastening means being part of the substrate (2) of the electronic foil (1,1′,1″).

A circuit board (3) is provided with a first rigid part (11) having a power system electronic component mounted thereon, a second rigid part (12) having a control system electronic component mounted thereon, and a thin flexible part (13) connecting the first and second rigid parts to each other. The flexible part (13) is provided with a plurality of conductive wires (27) conducted with the electronic components of the first and second rigid parts (11, 12). A non-conductive metal pattern (33) that is a dummy pattern is formed along an outer edge (13a) of the flexible part (13). By the non-conductive metal pattern (33), the disconnection of the conductive wires (27) due to cracking is suppressed.