A cable unit is provided comprising: a jacket comprising at least one cable housing and at least one support housing; the or each cable housing having a tubular structure, extending in a longitudinal direction, each support housing in the plurality of support housings having a tubular structure, extending in the longitudinal direction, wherein the at least one support housing being disposed on one side of the at least one cable housing; and at least one support element retained within each support housing of the plurality of support housings, wherein the at least one support element retained within each support housing of the plurality of support housings comprises at least one portion that has an arcuate cross section in the width direction.

The invention relates to a high-conductivity composite cable, a cable connector for the cable, as well as to a method for manufacturing the cable. The cable comprises a conductive layer comprising multiple busbars extending parallel to each other in one plane and separated from each other by a dielectric material. Each busbar is made of a homogeneous conductive material. First and second insulation layers are provided on the upper and bottom surface of the conductive layer, respectively. Each insulation layer is made of a polymer self-adhesive tape. A coating layer made of a paper or fabric self-adhesive tape is provided on at least one of the insulation layers. The cable further comprises a reinforcing relief structure on the coating layer(s) and multiple apertures each providing access to one of the busbars through the coating layer(s) and the insulation layer(s). The cable may transmit signals of different forms as accurately and quickly as possible.

A multiple circuit cable includes an inside transfer body that transfers a first signal or a first power, an inside insulator that covers an outer circumference of the inside transfer body, an outside transfer body that is disposed on an outside of the inside insulator and transfers a second signal or a second power, and an outside insulator that covers an outer circumference of the outside transfer body. The outside transfer body is configured with a plurality of conductive fibers having conductivity. The outside transfer body has a thickness so that an outer shape is a flattened into a flat-shape when an external force is applied.

A guarded coaxial cable assembly include one or more conductors, one or more rails, and an outer jacket, the orientation of the rail and the conductor(s) within the outer jacket operative to limit conductor or conductor jacket deformations such as deformations due to bends and transverse loads when the cable assembly is squeezed between a sash and a jamb.

A method of manufacturing an improved overhead or underground telephone lead-in cable for transmission services VVDL (voice, video, data and lead-in) that permits the connection of the users to the public telephone system with a high speed digital service link, besides the analog services required. The cable has at least one or a plurality of transmission circuits. One of the transmission circuit is formed by two metal conductor elements cooperating in turn to self-support the cable or a conventional type of impregnated fibers or kevlar tape. The second circuit which is formed by a stranded pair of conductors is impregnated with a swelling powder preventing moisture penetration.

An electrical power cable for high temperature environments comprises two or more sheathed conductors; each sheathed conductor comprising an electrical conductor, an electrical insulator surrounding the electrical conductor, and a sheath surrounding the electrical insulator; and a bonding material interconnecting the sheaths of the two or more sheathed conductors positioned adjacent to one another to form a cable.

Embodiments of a guarded coaxial cable assembly include one or more conductors, one or more rails, and an outer jacket covering these parts, the orientation of the rail and the conductor(s) within the outer jacket operative to limit conductor or conductor jacket deformations such as deformations due to bends and transverse loads when the cable assembly is squeezed between a sash and a jamb.

A modular planar electrical wiring system for providing a planar electrical wiring according to a desired configuration includes a planar electrical distribution cable, at least one planar electrical appliance embedded in a planar sheet and connectable to the planar electrical distribution cable; and at least one planar connector for connecting a corresponding planar electrical appliance to the electrical distribution cable at any given location therealong according to the desired configuration, to thereby provide a modular planar electrical wiring system having a low height profile. There is also provided a modular power distribution system provided with a power source, an enclosure for a planar power distribution cable, a crimp connector including a control system, and power sources for a planar modular power distribution system.

A guarded coaxial cable assembly includes a micro-coaxial cable and a metal rail for protecting the micro-coaxial cable from harmful compression.

A combined cable includes a row of cables having a plurality of cables separated from each other in a width direction of the combined cable, each of the cables extending in a length direction of the combined cable, a first film disposed on a side of the row of cables, and a second film disposed on another side of the row of cables opposite the first film in a thickness direction of the combined cable perpendicular to the width direction and the length direction. The first film and the second film are bonded to each of the cables. A portion of each of the first film and the second film between adjacent cables of the row of cables is not bonded together.