The present invention generally relates to a data communication cable (100) comprising: a set of elongated bodies (102) each formed from an elastic material and having an unextended free length; and for each elongated body (102), a set of conductive wires (104) disposed along the elongated body (102), such that each conductive wire (104) is extendable to more than the free length of the elongated body (102), wherein at least one conductive wire (104) is configured for communicating data between electronic devices; and wherein the conductive wires (104) are extendable in response to extension of the elongated body (102), such that the extended data communication cable (100) remains useable for said data communication between the electronic devices.

A wiring member includes: a plurality of wire-like transmission members; and a sheet material to which the plurality of wire-like transmission members are fixed, wherein a reinforcement part intersecting with at least one of the plurality of wire-like transmission members is provided to the sheet material.

In an example, a communication cable may include a first conductive cable wrapped in a fabric sheath, and a second conductive cable, also wrapped in a conductive sheath. Further, the communication cable may also include a breakable adhesive bonding the fabric sheath of the first conductive cable to the fabric sheath of the second conductive cable.

The present invention provides an FFC using a PCT film as an insulating coating layer. The FFC comprises a lower insulating coating layer made of the PCT film; a lower adhesive layer made of polyester formed through a lower primer layer made of polyurethane material on the upper surface of the lower insulating coating layer; an upper insulating coating layer made of the PCT film; an upper adhesive layer made of polyester formed through an upper primer layer made of polyurethane material on a lower surface of the upper insulating coating layer; and a conductor wire layer interposed between the lower adhesive layer and the upper adhesive layer.

An arrangement for assembling cables having cable processing devices arranged in parallel adjacent to one another wherein each cable processing device includes processing stations for processing cable ends of a cable, a cable conveying device running along a longitudinal machine axis for transporting the cable to at least one of the processing stations in the direction of the longitudinal machine axis, and a central control unit for operating the cable processing device which is arranged to a side of the cable processing device with respect to the longitudinal machine axis. The cable processing devices are arranged in at least one group with two adjacent cable processing devices, wherein due to a mirror-image configuration the central control units and the cable transport control units of the two adjacent cable processing devices forming the group are arranged facing and opposite one another to increase efficiency and ergonomics for an operator.

The present invention generally relates to a data communication cable (100) comprising: a set of elongated bodies (102) each formed from an elastic material and having an unextended free length; and for each elongated body (102), a set of conductive wires (104) disposed along the elongated body (102), such that each conductive wire (104) is extendable to more than the free length of the elongated body (102), wherein at least one conductive wire (104) is configured for communicating data between electronic devices; and wherein the conductive wires (104) are extendable in response to extension of the elongated body (102), such that the extended data communication cable (100) remains useable for said data communication between the electronic devices.

A cable structure includes isolation layers, a first signal wire, a second signal wire, a first ground wire, a second ground wire, a first conductor, and a second conductor. These signal and ground wires are parallel along a first direction and between the isolation layers. These signal wires are adjacent, and the ground wires are respectively at outer sides of these signal wires. The first conductor is on at least one of the isolation layers along a second direction orthogonal to the first direction and is electrically connected to the first and second ground wires. The second conductor is on an outer surface of at least one of the second isolation layers along the first direction and is electrically connected to the first conductor. The second conductor is symmetrical based on a central line between the first and second signal wires.

An arrangement for assembling cables having cable processing devices arranged in parallel adjacent to one another wherein each cable processing device includes processing stations for processing cable ends of a cable, a cable conveying device running along a longitudinal machine axis for transporting the cable to at least one of the processing stations in the direction of the longitudinal machine axis, and a central control unit for operating the cable processing device which is arranged to a side of the cable processing device with respect to the longitudinal machine axis. The cable processing devices are arranged in at least one group with two adjacent cable processing devices, wherein due to a mirror-image configuration the central control units and the cable transport control units of the two adjacent cable processing devices forming the group are arranged facing and opposite one another to increase efficiency and ergonomics for an operator.

A wiring member includes: a plurality of wire-like transmission members; and a sheet material to which the plurality of wire-like transmission members are fixed, wherein a reinforcement part intersecting with at least one of the plurality of wire-like transmission members is provided to the sheet material.

A substrate package includes a woven fabric having electrically non-conductive strands woven between electrically conductive strands including wire strands, co-axial strands, and/or an inductor pattern of strands. The package may be formed by an inexpensive and high throughput process that first weaves the non-conductive strands (e.g., glass) between the conductive strands to form a circuit board pattern of conductive strands in a woven fabric. Next, the woven fabric is impregnated with a resin material to form an impregnated fabric, which is then cured to form a cured fabric. The upper and lower surfaces of the cured fabric are subsequently planarized. Planarizing segments and exposes ends of the wire, co-axial, and inductor pattern strands. Since the conductive strands were formed integrally within the planarized woven fabric, the substrate has a high mechanical stability and provides conductor strand based electrical components built in situ in the substrate package.