Provided is a semiconductive resin composition which may be used for both an internal semiconductive layer and an internal semiconductive layer of a power cable, and in particular has excellent peelability to be used for the external semiconductive layer. In addition, a novel semiconductive resin composition having improved thermal resistance and mechanical physical properties, and an improved deterioration property is provided. The semiconductive resin composition for a cable includes: 1 to 15 parts by weight of a multiwalled carbon nanotube as a conductive particle, and 1 to 10 parts by weight of an enhancer, based on 100 parts by weight of a composite resin including 10 to 250 parts by weight of an ethylene-(meth)acrylate-based resin and 1 to 100 parts by weight of an olefinic elastomer, based on 100 parts by weight of a polypropylene-based resin.

The present disclosure discloses an HDMI photoelectric composite cable. The HDMI photoelectric composite cable includes: a sheath, an optical fiber unit, a plurality of signal control wires, a ground wire and fillers. The optical fiber unit includes one or more optical fibers and an optical fiber sheath uniformly extruded on a periphery of the optical fibers. The signal control wire includes a metal wire and an insulating layer uniformly extruded on a periphery of the metal wire. The ground wire is a metal conductor. The fillers are arranged on peripheries of the optical fiber unit, the plurality of signal control wires and the ground wire. The optical fiber unit, the plurality of signal control wires, the ground wire, and the fillers arranged on the peripheries thereof are covered by the shielding layer, and the shielding layer is covered by the sheath.

The present disclosure discloses an HDMI photoelectric composite cable. The HDMI photoelectric composite cable includes: a sheath, an optical fiber unit, a plurality of signal control wires, a ground wire and fillers. The optical fiber unit includes one or more optical fibers and an optical fiber sheath uniformly extruded on a periphery of the optical fibers. The signal control wire includes a metal wire and an insulating layer uniformly extruded on a periphery of the metal wire. The ground wire is a metal conductor. The fillers are arranged on peripheries of the optical fiber unit, the plurality of signal control wires and the ground wire. The optical fiber unit, the plurality of signal control wires, the ground wire, and the fillers arranged on the peripheries thereof are covered by the shielding layer, and the shielding layer is covered by the sheath.

A process produces an electrical line which extends in the longitudinal direction and the line has a line core and an outer shell. In a continuous shaping process, individual shell portions of the outer shell are formed successively by surrounding the line core with a curable plastic substance. In at least one portion, the outer shell is produced having a cross-sectional geometry which can be varied in the longitudinal direction of the line.

A process produces an electrical line which extends in the longitudinal direction and the line has a line core and an outer shell. In a continuous shaping process, individual shell portions of the outer shell are formed successively by surrounding the line core with a curable plastic substance. In at least one portion, the outer shell is produced having a cross-sectional geometry which can be varied in the longitudinal direction of the line.

The present invention is a cable, which carries signal, having an integrated coiling and reinforcing wrapper. The cable has a segment near an end that is stiffer than the cable generally. This segment can be bent by hand, and once bent, will retain its bent shape. If the flexible part of the cable is wrapped into a coil, or otherwise gathered together, then the stiffer portion can be bent around the gathered portion to secure it in its gathered form.

The present invention is a cable, which carries signal, having an integrated coiling and reinforcing wrapper. The cable has a segment near an end that is stiffer than the cable generally. This segment can be bent by hand, and once bent, will retain its bent shape. If the flexible part of the cable is wrapped into a coil, or otherwise gathered together, then the stiffer portion can be bent around the gathered portion to secure it in its gathered form.

It is disclosed a process and an apparatus for manufacturing a figure of eight cable. An extrusion head has separate extrusion dies extruding in parallel a first and second outer sheath around a first and second core, respectively, so as to provide two separate cable elements having respective longitudinal axes laying in a first plane. While the outer sheaths are in a softened state, the cable elements are passed in parallel through a twisting die which causes their longitudinal axes to lay in a second plane forming a predetermined twisting angle with respect to the first plane. This twisting causes the outer sheaths to join together, thereby forming a figure of eight cable.

It is disclosed a process and an apparatus for manufacturing a figure of eight cable. An extrusion head has separate extrusion dies extruding in parallel a first and second outer sheath around a first and second core, respectively, so as to provide two separate cable elements having respective longitudinal axes laying in a first plane. While the outer sheaths are in a softened state, the cable elements are passed in parallel through a twisting die which causes their longitudinal axes to lay in a second plane forming a predetermined twisting angle with respect to the first plane. This twisting causes the outer sheaths to join together, thereby forming a figure of eight cable.

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.