An electrical cable assembly comprising a first electrical circuit comprising at least two insulated conductors, a second electrical circuit, and a conductive metallic armor encasing the first and second electrical circuits, wherein the conductive metallic armor provides a return ground path. The second electrical circuit comprising at least two control insulated conductors, a jacket surrounding the control insulated conductors, and a wrap surrounding the jacket which is surrounding the control insulated conductors.

An apparatus configured to twist a first wire about a second wire is presented herein. The apparatus includes a securing mechanism configured to secure ends of the first wire and the second wire. The first wire is arranged parallel to the second wire along a longitudinal axis. The apparatus further includes a gripping mechanism configured to grip central portions of the first and second wires, a tensioning mechanism configured to apply a lateral offsetting force to the gripping mechanism, thereby deflecting the central portions of the first and second wires orthogonally from the longitudinal axis, and a rotating mechanism configured to rotate the gripping mechanism, thereby twisting the first and second wires about one another. A method of twisting a pair of wires is also presented.

This optical fiber cable is a central-core-type cable in which slotted rods are not used, and is composed of a core, a wrapper, a tension member, a ripcord, a sheath, and the like. The core is formed by twisting together a plurality of optical fiber units without back-twisting. The optical fiber units are formed by twisting together a plurality of intermittently-fixed optical fiber ribbons. A direction in which the optical fiber ribbons are twisted together is same as a direction in which the optical fiber units are twisted together.

This optical fiber cable is a central-core-type cable in which slotted rods are not used, and is composed of a core, a wrapper, a tension member, a ripcord, a sheath, and the like. The core is formed by twisting together a plurality of optical fiber units without back-twisting. The optical fiber units are formed by twisting together a plurality of intermittently-fixed optical fiber ribbons. A direction in which the optical fiber ribbons are twisted together is same as a direction in which the optical fiber units are twisted together.

Twisted-pair data cables are provided with conductors that are insulated with two or more different materials, where one of the two or more materials is cross-linked polyethylene (XLPE). The use of XLPE in conjunction with other materials within the same cable can ensure that the cable satisfies requirements of heat and flame resistance while reducing the manufacturing cost of such cables.

Twisted-pair data cables are provided with conductors that are insulated with two or more different materials, where one of the two or more materials is cross-linked polyethylene (XLPE). The use of XLPE in conjunction with other materials within the same cable can ensure that the cable satisfies requirements of heat and flame resistance while reducing the manufacturing cost of such cables.

A communication cable includes two-core communication wires, a drain wire, and a metal foil collectively covering the two-core communication wires and the drain wire. The two-core communication wires are twisted, and the metal foil is wound around the two-core communication wires with an adhesion strength of 1.21 MPa or more. Preferably, the two-core communication wires are twisted with a twist pitch of 20 mm or more and 60 mm or less. The communication cable further may include a restraint formed of a resin coating extruded around the metal foil or a resin film laterally wound around the metal foil.

A communication cable includes two-core communication wires, a drain wire, and a metal foil collectively covering the two-core communication wires and the drain wire. The two-core communication wires are twisted, and the metal foil is wound around the two-core communication wires with an adhesion strength of 1.21 MPa or more. Preferably, the two-core communication wires are twisted with a twist pitch of 20 mm or more and 60 mm or less. The communication cable further may include a restraint formed of a resin coating extruded around the metal foil or a resin film laterally wound around the metal foil.

A connector module provided on an end part of a communication cable used in communication of 100 Mbps or faster includes a first terminal, a connector member for accommodating the first terminal, a tubular shield member for covering an outer periphery of the connector member, and a tubular conductive rubber member to be electrically connected to the shield member. The shield member includes an accommodating portion for accommodating a part of the conductive rubber member on a side where an end part of the communication cable is inserted. The conductive rubber member includes a first region to be accommodated into the accommodating portion and a second region not to be accommodated into the accommodating portion. The first and second regions constitute an integrally molded body. The second region has a larger outer diameter than the first region.

A connector module provided on an end part of a communication cable used in communication of 100 Mbps or faster includes a first terminal, a connector member for accommodating the first terminal, a tubular shield member for covering an outer periphery of the connector member, and a tubular conductive rubber member to be electrically connected to the shield member. The shield member includes an accommodating portion for accommodating a part of the conductive rubber member on a side where an end part of the communication cable is inserted. The conductive rubber member includes a first region to be accommodated into the accommodating portion and a second region not to be accommodated into the accommodating portion. The first and second regions constitute an integrally molded body. The second region has a larger outer diameter than the first region.