Disclosed herein is a system and method of measuring for manufacture and deployment of distribution cable assemblies. The measurement includes a distribution cable ruler having at least one similar feature as a distribution cable of a distribution cable assembly. The at least one similar feature comprising at least one of an outer diameter, a bend radius, or a rigidity. The distribution cable ruler includes measurement indicia to facilitate measurement of a distribution length of the distribution cable of the distribution cable assembly. The method includes positioning a distribution cable ruler in a path intended for a distribution cable assembly. The method further includes measuring a distribution cable length of the distribution cable ruler using measurement indicia of the distribution cable ruler.

An adapting cable structure includes a cable, a first circuit board and a second circuit board. The cable is used to transfer a power signal or a control signal. The first circuit board includes a plurality of contacting parts and a plurality of first welding parts. Another end of the cable is on the second circuit board and the plurality of the contacting parts are located at two sides of the first circuit board. The plurality of welding parts are connected to one end of the cable. Furthermore, a pattern of a text or a specific design is placed on the cable. The pattern is used to improve the appearance or the identification of the cable.

A cable comprises: a cable core; and a cable sheath layer formed on the outside of the cable core, wherein the cable sheath layer has, on the outer surface thereof, a pattern corresponding to a binary code. A recognition rate is improved, and a problem of the productivity of the cable being reduced may be prevented by adjusting the widths of the pattern, corresponding to the binary code printed on the cable, in the vertical direction and the horizontal direction, and a plurality of patterns corresponding to the binary code printed on the cable are provided to prevent, even when the cable is buried in the ground or contacts a facility and a pattern corresponding to some binary patterns is not exposed, a pattern corresponding to the other binary patterns from being exposed and unrecognizable.

A cable comprises: a cable core; and a cable sheath layer formed on the outside of the cable core, wherein the cable sheath layer has, on the outer surface thereof, a pattern corresponding to a binary code. A recognition rate is improved, and a problem of the productivity of the cable being reduced may be prevented by adjusting the widths of the pattern, corresponding to the binary code printed on the cable, in the vertical direction and the horizontal direction, and a plurality of patterns corresponding to the binary code printed on the cable are provided to prevent, even when the cable is buried in the ground or contacts a facility and a pattern corresponding to some binary patterns is not exposed, a pattern corresponding to the other binary patterns from being exposed and unrecognizable.

A gripping element for arrangement on a component, wherein the component, in particular a cable harness, is of flexible design and has a changeable form, wherein the gripping element has at least one optically detectable marker via which a spatial orientation of the gripping element is detectable by an optical recognition device, and wherein the gripping element is grippable by a gripper.

Disclosed is a luminescent wire. The luminescent wire includes a silicone sleeve, a luminescent light bar and a flat cable, the silicone sleeve is internally provided with wire holes, the wire holes penetrate through the silicone sleeve along a longitudinal direction, each of the wire holes is used for one group of the flat cables to pass through, an end portion of the flat cable is connected to a plug or a socket, the flat cables inside each of the silicone sleeves may be used alone, or the plurality of the silicone sleeves may be selected to be used side by side, as to form different specifications of the luminescent wires. An accommodating hole is arranged above the wire holes, used to accommodate the luminescent light bar, the silicone sleeve is provided with a light transmitting area. The luminescent wire may also be conveniently viewed and used in darker environments.

Disclosed is a luminescent wire. The luminescent wire includes a silicone sleeve, a luminescent light bar and a flat cable, the silicone sleeve is internally provided with wire holes, the wire holes penetrate through the silicone sleeve along a longitudinal direction, each of the wire holes is used for one group of the flat cables to pass through, an end portion of the flat cable is connected to a plug or a socket, the flat cables inside each of the silicone sleeves may be used alone, or the plurality of the silicone sleeves may be selected to be used side by side, as to form different specifications of the luminescent wires. An accommodating hole is arranged above the wire holes, used to accommodate the luminescent light bar, the silicone sleeve is provided with a light transmitting area. The luminescent wire may also be conveniently viewed and used in darker environments.

A cable comprises: a cable core; and a cable sheath layer formed on the outside of the cable core, wherein the cable sheath layer has, on the outer surface thereof, a pattern corresponding to a binary code. A recognition rate is improved, and a problem of the productivity of the cable being reduced may be prevented by adjusting the widths of the pattern, corresponding to the binary code printed on the cable, in the vertical direction and the horizontal direction, and a plurality of patterns corresponding to the binary code printed on the cable are provided to prevent, even when the cable is buried in the ground or contacts a facility and a pattern corresponding to some binary patterns is not exposed, a pattern corresponding to the other binary patterns from being exposed and unrecognizable.

A cable comprises: a cable core; and a cable sheath layer formed on the outside of the cable core, wherein the cable sheath layer has, on the outer surface thereof, a pattern corresponding to a binary code. A recognition rate is improved, and a problem of the productivity of the cable being reduced may be prevented by adjusting the widths of the pattern, corresponding to the binary code printed on the cable, in the vertical direction and the horizontal direction, and a plurality of patterns corresponding to the binary code printed on the cable are provided to prevent, even when the cable is buried in the ground or contacts a facility and a pattern corresponding to some binary patterns is not exposed, a pattern corresponding to the other binary patterns from being exposed and unrecognizable.

A wiring member includes a plurality of wire-like transmission members. The plurality of wire-like transmission members are grouped into at least a plurality of first wire-like transmission members and a plurality of second wire-like transmission members in accordance with a predetermined condition regarding the plurality of wire-like transmission members. The wiring member includes a first flat wiring member including the plurality of first wire-like transmission members a second flat wiring member including the plurality of second wire-like transmission members. At least a part of the first flat wiring member and at least a part of the second flat wiring member are stacked.