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 method and method of using a cable that includes a cable core. The cable core has an inner armor wire layer disposed thereabout. The inner armor wire layer has an outer armor wire layer disposed thereabout. The inner armor wire layer and outer armor wire layer have torque removed therefrom during manufacturing.

Semi-automated (with manual feeding) and fully automated (with automated feeding) solutions for using a vision system to evaluate shield trim quality on shielded cables. The vision system uses a multiplicity of cameras and a corresponding multiplicity of mirrors in order to achieve a 360-degree view of the cable segment to be inspected. Cables to be inspected are positioned in a repeatable location based on the strip length of the cable (where the edge of the cable jacket is located relative to the end of the cable). The processing system receives a live image feed from the camera system and then uses color and dimensional analysis of the acquired images to determine whether the shield trim meets quality control specifications or not.

The present invention relates to an electric cable comprising:

at least one elongated electrical conductor (1),

at least one electrically insulating layer (2) surrounding said elongated electrical conductor (1),

at least one metal layer (3) surrounding said electrically insulating layer (2), characterized in that the metal layer (3) comprises metal nanowires.

A cable or a line and a method for producing a modified cable sheath (20) of an electric line or a cable (1) are provided and characterized by providing preferably spherical amorphous particles (30), and implanting the amorphous particles (30) into the cable sheath (20) in such a way that a plurality of the amorphous particles (30) penetrate into the surface of the cable sheath (20) just as deep as their diameter, less deep or only minimally deeper. Kinetic energy of the particles during bombardment is selected as a function of particle properties (e.g., size and/or mass) and at least one property of the cable sheath (e.g., strength of the cable sheath) such that the amorphous particles (30) penetrate into the surface of the cable sheath (20) as deep as their diameter, less deep or only minimally deeper than their diameter. The amorphous particles (30) can be glass spheres.

The present invention relates to an adhesive tape and to a method for jacketing an elongated item, more particularly cable sets. The adhesive tape must cure within the operational dictates for further processing, e.g. within 6 min, and after curing must exhibit the required dimensional stability properties. However, the adhesive compositions must not cure during storage itself, since otherwise they can no longer be used. Nor may the curing temperatures be too high, since otherwise the lead insulation, which is often made of PVC, may suffer damage. The invention provides a method for jacketing an elongated item such as more particularly leads or cable sets, where a stretched shrink-wrap film is guided in a helical line around the elongated item or the elongated item is wrapped in an axial direction by the stretched shrink-wrap film, the elongated item together with the shrink-wrap film wrapping is brought into the desired disposition, more particularly into the cable set plan, the elongated item is held in this disposition and the shrink-wrap film is brought to shrink by the supply of thermal energy at a temperature of up to 130 C.

A cable is composed of a linear shape conductor, a first electrical insulating member coating a periphery of the conductor, a shield made of a plating layer coating a surface of the first electrical insulating member, a second electrical insulating member coating a surface of the shield, and an exposed shield portion provided in at least one end portion of the cable with the second electrical insulating member being removed therefrom and the shield being exposed therein during termination. An adhesion strength between the shield and the second electrical insulating member in the exposed shield portion is lower than an adhesion strength between the shield and the second electrical insulating member in an other part of the surface of the shield.

Methods for forming continuous shields for use in a cable are provided. A first layer of longitudinally extending dielectric material may be provided, and a second layer of longitudinally extending electrically conductive material may be formed on the first layer. At a plurality of spaced locations along a longitudinal direction, respective gaps may be formed through both the first layer and the second layer, and each gap may span partially across a width of the second layer. Additionally, at each of the plurality of spaced locations, the gaps may result in the formation of one or more fusible elements of the electrically conductive material spanning between an adjacent set of longitudinally spaced segments of the electrically conductive material. Each fusible element may provide electrical continuity between the adjacent set of longitudinally spaced segment and may further have a minimum fusing current between 0.001 amperes and 0.500 amperes.

Provided is a method for manufacturing an electromagnetic interference shielding film comprising an electromagnetic interference shielding layer, the method comprising the steps of: preparing a metal nanoplate solution comprising a solvent in which metal nanoplates are dispersed; and coating the metal nanoplate solution on a substrate.

Semi-automated (with manual feeding) and fully automated (with automated feeding) solutions for using a vision system to evaluate shield trim quality on shielded cables. The vision system uses a multiplicity of cameras and a corresponding multiplicity of mirrors in order to achieve a 360-degree view of the cable segment to be inspected. Cables to be inspected are positioned in a repeatable location based on the strip length of the cable (where the edge of the cable jacket is located relative to the end of the cable). The processing system receives a live image feed from the camera system and then uses color and dimensional analysis of the acquired images to determine whether the shield trim meets quality control specifications or not.