An insulated wire capable of changing color when overheated under a current load includes an insulated core, at least one thermochromic strip, and a transparent plastic protective layer. The thermochromic strip is wound and fixed on the peripheral surface of the insulated core. The transparent plastic protective layer clads the peripheral surface of the insulated core and/or the top surface of the thermochromic strip. When the insulated core is overloaded and generates heat, the heat is transmitted to, and thereby changes the color of, the thermochromic strip. The color change is visible through the transparent plastic protective layer and can therefore alert the wire user in real time that the load on the insulated wire should be lowered.

A power cable and a power adaptor including the same are disclosed. The disclosed power adaptor comprises: an adaptor body; and a cable connected to the adaptor body, wherein the cable includes a plurality of conducting wires, which are arranged to be spaced in parallel to one another, and an outer skin, made of a transparent material, surrounding the plurality of conducting wires.

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 multiple circuit wiring assembly for discretely wiring a plurality of circuits with a single cable includes a set of first conductors each being placed in electrical communication with a first circuit. A set of second conductors is provided and each of the second conductors is each placed in electrical communication with a second circuit. A set of third conductors is provided and each of the third conductors is placed in electrical communication with a third circuit. Each of the sets of first, second and third conductors supplies a discrete power, neutral and ground for the respective first, second and third circuits. A sleeve is positioned around each of the sets of first, second and third conductors.

An AC electroluminescent power cord includes at least two electrode wires and a luminescent layer. The electrode wire is coated with the luminescent layer; the transparent or translucent plastic layer is coated on an outer wall of the luminescent layer; and each of the at least one electrode wire includes at least one metal wire; the at least two electrode wires are insulated with each other. When the electrode wires are conducted with an AC power source, the luminescent layer emits light. The AC electroluminescent power cord of the disclosure not only has a simple and reliable structure, but also has a display function. When applied for various electronic devices, the AC electroluminescent power cord of the disclosure integrally emits light or sequentially emits light in sections to simulate and display the current flow.

A cable includes a transmissive core; a jacket surrounding the transmissive core, which has at least an outermost polymeric layer; and an external semi-conductive layer around and in direct contact with the outermost polymeric layer of the jacket. The external semi-conductive layer is made of a composition comprising a base polymer material and an electrically conductive filler. The electrically conductive filler includes carbon nanotubes.

A multi-striped electrical cable may be provided. The multi-striped electrical cable may comprise a conductor, an inner layer, an outer layer, and a stripe. The conductor core may comprise a conductor. The inner layer may be around the conductor core and may comprise an inner layer polymer. The outer layer may be around the inner layer. The outer layer may comprise an outer layer polymer, an outer layer colorant, and an outer layer friction reducing additive. The stripe may be disposed on an outermost portion of the outer layer. The stripe may comprise a stripe polymer, a stripe colorant, and a stripe friction reducing additive.

Provided is a coated carbon nanotube electric wire superior in identifiability. The coated carbon nanotube electric wire includes: a carbon nanotube wire including one or a plurality of carbon nanotube aggregates formed by a plurality of carbon nanotubes; and an insulating coating layer coating the carbon nanotube wire, wherein the insulating coating layer has an identification mark.

A process for coloring post-production cables or coloring cables in an in-line manufacturing process can include coloring a polymer coated conductive cable or wire using a colorant solution. In one example, the wire can be passed through a trough, bath or spray of the colorant solution. In one example, the colorant can have a transparent characteristic to it in order to allow the printing on the cable to show through the colorant applied to the cable.

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.