The invention relates to a method for producing an electric cable (2), according to which method the electric cable (2) is successively processed in independent processing modules (46, 47, 48). According to the invention, the electric cable (2), a sheath clamp (49) fixed on a cable sheath (18) of the cable (2), and/or a cable carrier (4) associated with the electric cable (2) during the processing thereof is rendered identifiable with an information carrier (9, 10), wherein documentation (13) of the processing of the electric cable (2) for at least one processing process of one of the processing modules (46, 47, 48) is created and associated with the electric cable (2).

A multi-core cable includes a plurality of coaxial cables being arranged in parallel with each other, and a synthetic resin covering member that collectively covers the plurality of coaxial cables. Each coaxial cable includes a center conductor, an insulator covering an outer periphery of the center conductor, and a metal outer conductor covering an outer periphery of the insulator. The covering member holds the plurality of coaxial cables in such a manner that the plurality of coaxial cables are aligned side by side along a direction perpendicular to a longitudinal direction of the plurality of coaxial cables. At least a part of the outer conductors of the plurality of the coaxial cables respectively contacts the covering member.

A cable with a tactile twist indicator, wherein the cable has at least one core for signal transmission and a cable sheath surrounding the at least one core, wherein the cable has precisely one tactile twist indicator, which extends along a longitudinal direction of the cable over essentially the entire length of the cable sheath and which has a predetermined orientation relative to the at least one core over essentially the entire length of the cable sheath.

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.

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.

An object of the present disclosure is to provide a technique that can prevent, in a wire harness including a fixing member, the fixing member from being attached in a deviated orientation. A wire harness includes: a wiring member; a fixing member provided on the wiring member; and a first reference mark and a second reference mark that are each provided at a position of the wiring member that corresponds to the fixing member. The first reference mark and the second reference mark each have a distinctive external appearance in a circumferential direction of the wiring member. The first reference mark indicates a reference position of the wiring member in the circumferential direction, and the second reference mark indicates a position of the wiring member in the circumferential direction, the position serving as a reference for an attachment orientation of the fixing member.

A heating device for a lens, and an optical camera and a method for manufacturing same. A lens (1000) comprises a lens body, the lens body has a first surface (1100) and a second surface (1200) which are opposite to each other, and an edge (1300) that connects the first surface (1100) and the second surface (1200). The 5 heating device (1400) comprises: a heating unit adapted to be arranged on the edge (1300) of the lens body and used for transferring heat to the lens body after being powered. The heating device (1400) can achieve at least one of the beneficial effects such as a simple structure, high heat efficiency, uniform heating, safety in use, and strong weather resistance.

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.

The present disclosure describes cable cuffs. A cable cuff may include a first half including a main body with a first cable recess and a first securing feature, and a second half including a main body with a second cable recess and a second securing feature. The first cable recess may include a first flex retention section and the second cable recess may include a second flex retention section. The first half and the second half may be connected via a hinge. The first half is mated with the second half such that the first and second cable recesses form a pocket for receiving and grasping a cable. The first and second securing features engage to maintain the first half and the second half in a mated condition. The first and second flex retention sections reside within and extend into the pocket to engage a cable grasped therein. Cable management systems are also provided herein.

The present disclosure relates to a color-coded cable identification assembly and a cable. The cable identification assembly comprises: a support element including a fixing element adapted to fix the support element to a cable; and a plurality of identification elements, which are detachably mounted on the support element with the cable being located between the support element and the plurality of identification elements. Each identification element has a predetermined color so that the plurality of identification elements are capable of forming a predetermined color code to identify the cable. The cable identification assembly according to the present disclosure can be very easily and rapidly mounted to the cable, thereby greatly saving the installation time of workers and thus reducing the labor cost and the chance of making a mistake. Compared with a conventional adhesive tape, the cable identification assembly according to the present disclosure can meet the requirements such as anti-ultraviolet, anti-aging and reuse, thereby further reducing the cost of the cable identification assembly.