A cable includes a plurality of wires, an wrapping tape covering the outside of the wires, a shielding layer coated on the outside of the wrapping tape and an insulating cover coated on the outside of the shielding layer, the shielding layer includes a plurality of conductors, wherein the shielding layer includes fibers mixed with the conductors.

A cable management assembly may include a cable management spiral and a cable bundle in operative engagement to the cable management spiral. The cable management spiral may be a spring coil, such as a stainless steel spring coil. Heat shrink wrap and/or sheathing may be used to operatively engage the cable bundle to the cable management spiral. The cable management assembly may be installed on a telescoping mast assembly.

A multilayered textile sleeve for routing and protecting elongate members and method of construction thereof are provided. The multilayered textile sleeve includes a plurality of textile layers overlying one another to form a multilayered tubular wall extending lengthwise about a central axis between opposite open ends. The plurality of textile layers include a textile innermost layer and a textile outer layer. At least one silicone layer is sandwiched between the textile innermost layer and the textile outer layer.

Resilient air-cooled induction heating cables are disclosed. An example cable assembly includes: a plurality of conductors in a Litz cable arrangement; a layer of magnet wire insulation over the Litz cable arrangement; an inner silicone dielectric jacket over the layer of magnet wire insulation; and an outer silicone jacket over the inner silicone dielectric jacket.

A cable with braided shield includes a conductor, an insulation layer arranged to cover a periphery of the conductor, a braided shield layer arranged to cover a periphery of the insulation layer, and a sheath arranged to cover a periphery of the braided shield layer. The braided shield layer includes a braided shield braided to cross a copper tinsel wire and a metal wire. An outer diameter D1 of the copper tinsel wire is larger than an outer diameter D2 of the metal wire.

Provided is a power cable that contains at least one insulated conductor extending along a cable longitudinal direction; a bedding layer surrounding the at least one insulated conductor, and a non-metallic armour surrounding the bedding layer. The non-metallic armour is made by at least one meshed tape helically wound onto the bedding layer and has an openness factor of at least 30% and a meshed tape tear resistance of at least 200 N according to DIN 53363 of 2003.

A braid includes a plurality of metal-plated bundles braided to each other, each of the metal-plated bundle having a flattened shape. Each of the metal-plated bundle includes a plurality of tensile strength fibers, a plurality of first metal plating portions that are formed on the tensile strength fibers respectively, and a second metal plating portion including the first metal plating portions therein, the first metal plating portions having the tensile strength fibers respectively.

A wire harness including a number of wires, an outer sheath layer, and an anisotropic fabric positioned between the wires and outer sheath is provided. The anisotropic fabric is formed from combining a number of more rigid, monofilament fill strands and a number of less rigid multifilament warp strands. The fill strands may be formed from a single filament of at least five hundred fifty (550) denier while the warp strands may be formed from a series of polyester threads of at least two hundred (200) denier. The anisotropic layer permits limited rotation of the inner wires relative to the outer sheath when exposed to friction and pressure and is not subjected to significant creep during use.

A method and a structure for positioning and wrapping wire leads involve providing two leads of a transmission wire for transmitting power and/or signal with appropriate orientational limit therebetween by: wrapping a predetermined range of the two leads extending from a predetermined object with one or more segments of strip-shaped net for orientational limit that maintain independent extension and juxtaposition of the two leads, so as to prevent the leads of the transmission wire from entwining with each other after frequent orientational change caused by an external force.

This document describes techniques and devices for preventing false positives with an interactive cord. An interactive cord includes a cable, and fabric cover that covers the cable. The fabric cover includes one or more conductive threads woven into the fabric cover to form one or more capacitive touchpoints which are configured to enable reception of touch input that causes a change in capacitance to the one or more conductive threads. A controller, implemented at the interactive cord or a computing device coupled to the interactive cord, can detect the change in capacitance and trigger one or more functions associated with the one or more capacitive touchpoints. In one or more implementations, the interactive cord is designed to prevent false positives which may occur from accidental contact with the touchpoints, such as when the interactive cord makes contact with the user's body or a conductive surface.