An electrically insulated cable comprising: a core electric wire; a tape member covering the core electric wire; and a covering layer covering the tape member; wherein: the core electric wire includes a plurality of insulated electric wires; the insulated electric wires each include a conductor and an insulating layer covering the conductor; and the tape member has a minimum value of transmittance of 70% or more with respect to light having a wavelength of no less than 400 nm and no more than 800 nm.

There are provided a conductor for busbar electric wire, and a busbar electric wire configured by a conductive plate material having a substantially rectangular cross-sectional shape, the conductor including: an opening formed on one side in a width direction orthogonal to a longitudinal direction of the plate material, the width direction corresponding to a planar direction of the plate material.

There are provided a conductor for busbar electric wire, and a busbar electric wire configured by a conductive plate material having a substantially rectangular cross-sectional shape, the conductor including: an opening formed on one side in a width direction orthogonal to a longitudinal direction of the plate material, the width direction corresponding to a planar direction of the plate material.

Cables that include a conductor and an optical fiber. In some embodiments, the cable can include an optical fiber loosely disposed within an enclosure. A conductor layer can be disposed about the enclosure. An insulation layer can be disposed about the at least one conductor layer. An inner layer of armor strength members can be helically disposed about the insulation layer. An outer layer of armor strength members can be helically disposed about the inner layer of armor strength members. The armor strength members in the outer layer of armor strength members can be at an opposite helix compared to the armor strength members in the inner layer of armor strength members. An outer jacket can be disposed about the outer layer. In other embodiments, the cable can include an optical fiber in a coupled electro-optical package, where the conductor layer can be disposed about the electro-optical package.

The present invention relates to an elongated elastic seam tape comprising an elongated elastic conductor as well as to a method of manufacturing such an elongated elastic seam tape.

The present invention relates to a coating process and a process system for a cable, and a cable manufactured thereby. The process includes: (1) providing the cable; (2) transporting the cable into immersion device, the cable immerged in first solution to form first coating layer thereon; (3) transporting the cable out of the immersion; (4) transporting the cable into coating device through third wire die, the cable immerged in second solution to form second coating layer thereon, the second layer is attached to the cable through the first layer; (5) transporting the cable out of the coating device through fourth wire die, fourth aperture diameter of the fourth wire die is larger than third aperture diameter of the third wire die; and (6) heating the cable to cure the second coating layer. The system includes: a cable providing device; an immersion device; a coating device; and a heating device.

A transmission line includes a conductor for signal transmission. The transmission line also includes a plurality of isolating individuals arranged to cover the conductor as an isolating layer of the transmission line. The isolating layer has at least one air gap.

A shielded flat cable includes a first differential signal line pair including mutually parallel first and second signal lines, first and second ground lines parallel to the first differential signal line pair arranged between the first and second ground lines, an insulating layer covering the first differential signal line pair, the first and second ground lines, a first shielding layer covering a first surface of the insulating layer, and a second shielding layer covering a second surface of the insulating layer, opposite to the first surface. The insulating layer includes an opening exposing the first ground line at the first surface of the insulating layer, and the first shielding layer is electrically connected to the first ground line through the opening. A width of the first ground line is greater than a width of each of the first and second signal lines.

The present invention relates generally to a method of manufacturing far-infrared radiation thermal wire and far-infrared radiation thermal wire thereby, more particularly, a method of manufacturing far-infrared radiation thermal wire and far-infrared radiation thermal wire manufactured thereby, in which electric power is supplied with a predetermined resistance value. According to an embodiment of the present invention, a method of manufacturing far-infrared radiation thermal wire comprise steps of: making microfine wire that emits far-infrared radiation as it generates heat according to the resistance value when electricity is flowed in; making one strand of thermal wire by bundling many strands of the microfine wire that are in contact of each other; and making two or more groups each of the groups having different resistance value and comprising one or more microfine wires that have identical resistance value in order to make the bundle into an effective geometric structure that well radiates electric dipole radiation while emitting far-infrared radiation.

A communications cable is provided that includes a pair of twisted pair of wires, each coated with a fluoropolymer insulator. The twisted pair of wires is configured to carry a differential signal, such as a differential data signal and/or a differential power signal. The fluoropolymers are highly effective insulators and significantly reduce both the effects of internal and external electromagnetic interference while maintaining low cable attenuation, even when operating within a temperature range of −40° C. to 150° C.