A door wiring module includes: a door functional planar member; a wiring member wired on and held by the door functional planar member; and an exterior member in which a part of the wiring member extending to an outer side from the door functional planar member and incorporated into the door is wired and held. The door wiring module is provided to be able to be folded so that the exterior member overlaps with the door functional planar member before being incorporated into the door, and is incorporated into the door in a state where the exterior member is developed.

A wiring harness assembly includes a first flexible planar wire cable. The first flexible planar wire cable has a first plurality of separated conductors formed in a first insulating layer. The first insulating layer includes a first flat exterior surface. The first flat exterior surface defines first apertures that expose at least a portion the first plurality of separated conductors. The first apertures are sized, shaped, and arranged such that arranging a second flat exterior surface of a second flexible planar wire cable in contact with the first flat exterior surface enables an electrical connection between the first plurality of separated conductors and a second plurality of separated conductors formed in a second insulating layer of the second flexible planar wire cable.

A circuit board assembly has a circuit board and a high-speed cable. The high-speed cable has two signal lines, a ground conductor, an impedance-reducing conductor, and a covering material. The signal lines, the ground conductor, and the impedance-reducing conductor are mounted through the entire high-speed cable. The covering material wraps the signal lines, the ground conductor, and the impedance-reducing conductor, and has a conductive layer and an isolation layer as an inner layer and an outer layer respectively. The conductive layer has multiple loops electrically connected to the ground conductor and the impedance-reducing conductor. Thus, the impedance in the covering material, the ground conductor, and the impedance-reducing conductor is decreased, which prevents from attenuating the signal intensity during transmission at high frequency.

A vehicle circuit body is provided. The vehicle circuit body includes a bent portion which is formed by bending a plurality of conductor plates with a convex shape toward one side of a lamination direction in which the plurality of conductor plates are laminated, the plurality of conductor plates being laminated such that adjacent conductor plates are spaced apart from each other; and a rigid portion where the plurality of conductor plates extending from the bent portion are joined together to form a single layer. The bent portion is arranged at a position which faces an inner corner or outer corner of a concave-convex shape formed on a body panel.

A method and device are provided. The device includes a system component that has a circuit board that includes a cable connection portion. The cable connection portion is disposed on and extends along a mounting surface, and includes board pads disposed on the mounting surface within the cable connection portion. The board pads define corresponding board contact surfaces for electrical coupling with connector pads, and include a board adhesive material disposed on the corresponding board contact surfaces.

A method of forming an electrical cable assembly includes providing a multiconductor flat cable comprising wires arranged in a coplanar fashion with each other and encased within a planar dielectric structure, cutting a slot in the planar dielectric structure intermediate the wires, thereby forming wing features in the dielectric structure extending from the wires, removing portions of the dielectric structure from ends of the wires, wherein portions of wing features remain, attaching the exposed wires to terminals, wherein the terminals define prongs, and attaching the portions of the wing features to by inserting the prongs within holes defined in the portions of the wing features, thereby retaining the wires to the terminals.

The application discloses a flat cable assembly, which includes a plurality of cables arranged in a row and an insulating film. The cables have a center line and include connecting portions, a signal wire and a grounding wire respectively. The connection portions are located on one side of the center line. The insulating film is disposed on the connecting portion of any one of the cables and located on one side of the central line. The cables are exposed from the insulating film. The insulating film is disposed on a single side of the cables, whereby the cables are exposed from the insulating film. The flat cable assembly is easily manufactured and the amount of the cables therein can be varied according to real practice condition. The grounding wire is integrated to each cable, whereby the flat cable assembly has an excellent anti-EMI effect and performance in signal transmission.

Provided herein are systems and methods for manufacturing a cable. In some embodiments, a system for manufacturing a cable includes a joining mechanism configured to join the upper conducting foil and the lower conducting foil; and a linear actuator configured to control motion of the joining mechanism with respect to the upper conducting foil and the lower conducting foil. In some embodiments, a system for manufacturing a cable includes: an electrode configured to join the upper conducting foil and the lower conducting foil in a region between insulated conductors of the plurality of insulated conductors; and a plurality of rollers configured to position the upper conducting foil, the lower conducting foil, and the plurality of insulated conductors relative to the electrode.

A shielded electrical cable includes conductor sets extending along a length of the cable and spaced apart from each other along a width of the cable. First and second shielding films are disposed on opposite sides of the cable and include cover portions and pinched portions arranged such that, in transverse cross section, the cover portions of the films in combination substantially surround each conductor set. An adhesive layer bonds the shielding films together in the pinched portions of the cable. A transverse bending of the cable at a cable location of no more than 180 degrees over an inner radius of at most 2 mm causes a cable impedance of the selected insulated conductor proximate the cable location to vary by no more than 2 percent from an initial cable impedance measured at the cable location in an unbent configuration.

An adapting cable structure includes a cable, a first circuit board and a second circuit board. The cable is used to transfer a power signal or a control signal. The first circuit board includes a plurality of contacting parts and a plurality of first welding parts. Another end of the cable is on the second circuit board and the plurality of the contacting parts are located at two sides of the first circuit board. The plurality of welding parts are connected to one end of the cable. Furthermore, a pattern of a text or a specific design is placed on the cable. The pattern is used to improve the appearance or the identification of the cable.