A multi-conductor cable for a vehicle includes core wires respectively having a conductor formed by a plurality of twisted wires, and an insulating layer covering an outer periphery of the conductor, and a sheath layer disposed around the core wires. A marking portion is partially formed on an outer peripheral surface of the sheath layer, and a ratio of an arithmetic average roughness Ra2 of a peripheral region adjacent to the marking portion, with respect to an arithmetic average roughness Ra1 of the marking portion, at the outer peripheral surface, is 0.10 or greater and 0.90 or less.

A wiring harness assembly includes a plurality of electrically conductive wires encased within a substrate formed of a dielectric material, a location feature integrally formed with the substrate, and an opening defined in the substrate located within a predetermined tolerance relative to the location feature. A section of the plurality of electrically conductive wires is exposed within the opening.

The present invention relates to a thermal line (1) for transmitting an electrical signal to a module block (5) comprising a group of connections for electrical contact to be made by the thermal line (1), and to a system of module blocks. The thermal line (1) comprises a first core (2a) and a second core (3a), a first core insulation material (2b) and a second core insulation material (3b) and also an external insulation material (4), wherein the first core (2a) is sheathed at least once by the first core insulation material (2b) and forms a first line element (2), and the second core (3a) is sheathed at least once by the second core insulation material (3b) and/or is separately sheathed at least once by the external insulation material (4) and forms a second line element (3). Furthermore, the first line element (2) has a first outside diameter (D1) and the second line element (3) has a second outside diameter (D2), wherein the first outside diameter (D1) differs from the second outside diameter (D2). The two line elements (2, 3) are jointly sheathed at least once by the external insulation material (4) in such a way that the cross section of the thermal line (1) has a coding which is secured against reversal.

An automatic wire arranging device includes a controller, at least one driving device electrically connected with the controller, a wire clamping jig, a wire arranging rotor, at least one charge-coupled device camera and a puncher pin. The wire clamping jig is connected with the at least one driving device. The wire arranging rotor has a spindle, and a cylinder-shaped base portion fastened to a tail end of the spindle. An outer side surface of the base portion is equipped with a plurality of clamping portions. The plurality of the clamping portions are used for clamping a plurality of different characteristic core wires. The wire arranging rotor is connected with the at least one driving device. The at least one charge-coupled device camera faces towards the wire clamping jig and is connected with the controller. The puncher pin is movably disposed above the wire clamping jig.

A wiring harness assembly includes a plurality of separated conductors formed of an electrically conductive material, a substrate formed of a dielectric material encasing the plurality of separated conductors, a location feature integrally formed with the substrate and an opening defined in the substrate having a predetermined size and shape. A section of the plurality of separated conductors is exposed within the opening. The opening is precisely located relative to the location feature.

A cable, which can serve as a mounting device for sensors, includes strands to be connected to the sensors. The strands are formed as a braided wire bundle. An insulating layer is provided on a surface of each of the strands in order to prevent mutual electric conduction of the strands. A particular braided bundle can be specified from among many braided bundles by using, as two indicators, a combination of colors of the insulating layers and a twist direction of the braided bundle.

An automatic wire arranging device includes a controller, at least one driving device electrically connected with the controller, a wire clamping jig, a wire arranging rotor, at least one charge-coupled device camera and a puncher pin. The wire clamping jig is connected with the at least one driving device. The wire arranging rotor has a spindle, and a cylinder-shaped base portion fastened to a tail end of the spindle. An outer side surface of the base portion is equipped with a plurality of clamping portions. The plurality of the clamping portions are used for clamping a plurality of different characteristic core wires. The wire arranging rotor is connected with the at least one driving device. The at least one charge-coupled device camera faces towards the wire clamping jig and is connected with the controller. The puncher pin is movably disposed above the wire clamping jig.

Strands to be connected to sensors are formed as a braided wire, an insulating layer is provided on a surface of each of the strands in order to prevent mutual electric conduction of the strands, and a particular braided bundle can be specified from among many braided bundles using a combination of colors of the insulating layers and a twist direction of the braided bundle that constitutes the braided wire as two indicators, whereby a cable having a sufficiently small diameter and excellent flexibility even when many sensors are mounted thereon is provided.

A power cord structure is disclosed, comprising a conductive cord body consisting of plural conductive cords which are mutually entangled at a twist distance satisfying security requirements, and an opaque insulation protective outer layer, wherein the insulation protective outer layer includes an insulation cladding layer and a spiral color correspondence layer, the insulation cladding layer is wrapped around the outside of the conductive cord body; also, the spiral color correspondence layer spirally displays on the outer surface of the insulation cladding layer with at least three color segments, and the interval widths of such at least three color segments are in a proportional ratio to the twist distance satisfying security requirements of the plural conductive cords.

A wiring harness assembly includes a plurality of separated conductors formed of an electrically conductive material, a substrate formed of a dielectric material encasing the plurality of separated conductors, a location feature integrally formed with the substrate and an opening defined in the substrate having a predetermined size and shape. A section of the plurality of separated conductors is exposed within the opening. The opening is precisely located relative to the location feature.