A Metal-Clad (MC) cable assembly is provided. In one approach, the MC cable assembly includes a core having a plurality of conductors laid parallel to one another, each of the plurality of conductors including an electrical conductor and insulation, with or without a jacket layer. The MC cable assembly further includes a metal sheath disposed over the core. In some approaches, the MC cable assembly further includes an assembly tape disposed around the plurality of conductors. In some approaches, the MC cable assembly further includes a subassembly having a set of conductors, and an assembly jacket layer disposed over the subassembly. In some approaches, a polymeric protective layer is provided over an insulation layer of one or more of the plurality of conductors and the subassembly. In some approaches, a bonding/grounding conductor may also be cabled with the plurality of conductors.

A method of forming a flexible circuit, including providing a flexible flat cable with a first surface and a second surface. The first surface of the flexible flat cable is diametrically opposed to the second surface. A dispensing apparatus including a nozzle is further provided, and an extruded material is dispensed through the nozzle onto the first surface of the flexible flat cable. The extruded material is shaped into a pattern and cured onto the first surface of the flexible flat cable.

A cable with a non-circular ground wire is provided, including two wires, two ground wires, and an insulating tape; wherein the inner sides of the wires are in contact with each other; the ground wires are respectively arranged on two opposite sides of the wires; each ground wire at least includes a first side, a second side, and a third side; the first and second sides respectively contact the outer surfaces of the two wires, and the shapes of the first side and the second side respectively correspond to the shapes of the outer surfaces of the two wires; the insulating tape covers the outer surfaces of the wires and the third sides of the ground wires. Thereby, the mechanical properties of the cable of the present invention, such as small impedance variation of high-frequency signal transmission, transmission stability, structural flexibility and bending, can be significantly improved.

A high voltage alternative current cable is provided having mechanically reinforced electric conductor, by having a reinforcement member at the centre of the conductors of the cable, where the reinforcement member is made of one or more low or non-magnetic steel wires, one or more wires of CuNiSi precipitation alloy, or one or more aluminium wires made of an EN AW-1xxx, EN AW-2xxx, EN AW-5xxx, AW-6xxx, EN AW-7xxx, or EN AW-8xxx alloy, according to the European aluminium standard.

Described are cables for connecting components of computing systems. The cables improve automation and resulting performance of high frequency and/or high speed signal transmissions by providing reliable transmission paths between hardware components. An example cable includes parallel conductors and a dielectric core that secures the parallel conductors along the length using parallel channels in opposite sides of the dielectric core. An alignment structure is also formed in the dielectric core, which has a shape along the length of the cable. A cable jacket surrounds the parallel conductors and the dielectric core. The cable jacket is contoured to follow the shape of the alignment structure. The dielectric core can be formed to maintain consistent separation between the parallel channels along the length of the cable to match impedance of the parallel conductors along the length of the cable, whether the cable lays flat or bends around corners.

A lighter and more space-saving wire harness that has a function of retaining the shape of part of electric wires and an electromagnetic shield function. The wire harness includes a plurality of spliced and sheathed electric wires and a conductive shielding member. Each of the spliced and sheathed electric wires has a spliced core wire and an insulating sheath that covers the spliced core wire. The spliced core wire includes a first core wire that is a single conductive wire, and a second core wire that is a bundle of a plurality of conductive wires that are thinner and shorter than the first core wire, the second core wire being connected to an end portion of the first core wire. The shielding member is formed in a flexible tubular shape, and collectively covers the plurality of spliced and sheathed electric wires.

A flat cable includes: a plurality of conductors arranged in parallel; an insulating layer formed, on first surfaces of the plurality of conductors and on second surfaces that are opposite surfaces of the first surfaces, along the plurality of conductors; an exposed portion where the first surfaces at end portions of the conductors are exposed to outside; and a reinforcement plate formed on the second surfaces opposite to the exposed portion. On the second surfaces opposite to the exposed portion, the reinforcement plate is directly formed on the conductors, and on the second surfaces opposite to the first surfaces that are in continuous with the exposed portion, the reinforcement plate is formed between the conductors and the insulating layer on the second surfaces.

Cables, cable connectors, and support structures for cantilever package and/or cable attachment may be fabricated using additive processes, such as a coldspray technique, for integrated circuit assemblies. In one embodiment, cable connectors may be additively fabricated directly on an electronic substrate. In another embodiment, seam lines of cables and/or between cables and cable connectors may be additively fused. In a further embodiment, integrated circuit assembly attachment and/or cable attachment support structures may be additively formed on an integrated circuit assembly.

Cables, cable connectors, and support structures for cantilever package and/or cable attachment may be fabricated using additive processes, such as a coldspray technique, for integrated circuit assemblies. In one embodiment, cable connectors may be additively fabricated directly on an electronic substrate. In another embodiment, seam lines of cables and/or between cables and cable connectors may be additively fused. In a further embodiment, integrated circuit assembly attachment and/or cable attachment support structures may be additively formed on an integrated circuit assembly.

A fabric wrapped cable is formed by positioning adhesive on opposed layers of fabric. A cable is positioned between those layers and the layers are attached by attaching the adhesive of one layer to the adhesive of the other layer. In forming the wrapped cable in such a manner, the cable is provided with at least one wing.