An electric wire processing device includes a comb-shaped jig having a plurality of comb teeth; and a drive mechanism configured to, in a state in which at least one electric wire is sandwiched between the plurality of comb teeth, slide the comb-shaped jig on the at least one electric wire.

A cable processing device includes a cable clamping device for clamping a cable to be processed. The device further includes a core wire straightening device for straightening exposed core wires of the fixed cable, and a core wire separating device for separating the straightened two core wires by a predetermined spacing.

A bus bar includes members made from a conductive material and consecutively arranged to form a plate shape defining a wiring pathway. The members adjacent to each other are connected to each other by laser joining. The members include connection members arranged at both ends of the wiring pathway and having connection portions for electrical input-output, and a conductive member arranged between the connection members. In the members, only the connection members are plated.

A cable holding system for positioning a cable relative to a cable processing machine comprises a cable holding device for selectively clamping onto a cable to be processed, and a receiver. The receiver includes an opening for selectively receiving the cable holding device in a predetermined orientation, and a mounting base for fixing the location of the receiver relative to the cable processing machine.

The present invention relates to a method for producing carbon nanostructures using a fluidized bed reactor. According to the method, some of the as-produced carbon nanostructures remain uncollected and are used as fluidic materials to improve the fluidity in the reactor. The method enables the production of carbon nanostructures in a continuous process. In addition, the fluidity of the catalyst and the fluidic materials in the reactor is optimized, making the production of carbon nanostructures efficient.

Provided are a flat cable and a manufacturing method thereof, and particularly, a flat cable including: a pod including pipe type insertion portions formed to be separated from each other by a predetermined distance at both side ends thereof and a central insertion portion of which both ends are integrally connected to the both pipe type insertion portions; a pair of left and right support members inserted into the pipe insertion portions; and multiple electric cables inserted into the central insertion portion and the central insertion portion of the pod is partitioned into multiple spaces separated from each other and multiple electric cables 30 are horizontally disposed in the separated spaces in one layer to minimize mutual entangling or friction of the electric cables.

Provided is a coating for forming a conductive release layer capable of forming a conductive release layer having high adhesion to a film base material, suppressing deterioration in conductivity over time in the air, and having a sufficient releasing property. The coating for forming a conductive release layer of the present invention contains a conductive composite including a π-conjugated conductive polymer and a polyanion, an epoxy compound having an epoxy group, a curable silicone, a polyester resin, and an organic solvent.

A flexible flat cable (FFC) includes a first insulation layer, at least one pair of conductors, a plurality of low-k dielectric layers, two second insulation layers, and at least one shielding layer. The pair of conductors is located within the first insulation layer. Each pair of conductors includes a plurality of first conductors, and the first conductors are axially extending and arranged in parallel. The low-k dielectric layers are embedded in the first insulation layer. Each of the pair of conductors or each of the first conductors is covered and surrounded with one low-k dielectric layer. The two second insulation layers are located on two surfaces of the first insulation layer. The shielding layer is located on the two second insulation layers opposite to the first insulation layer.

In wire processing systems and methods, a wire channel receives a wire. One or more fluid guides flow the fluid into the wire channel to move, along the wire, a component (e.g. a solder sleeve) positioned at least partially in the wire channel and coupled to the wire. Other features are also provided.

A system and method for manufacturing wire and cable products with a polymer cable component is provided. The systems and methods include increasing the hardness of a polymer cable component in order to reduce compression and deformation of the cable components during manufacturing. In some instances, the hardness is temporarily increased prior to or during the process of creating twisted pair or during the cabling process.