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.

A method for producing a film, the method including separately discharging a slurry containing particles of a layered material in a liquid medium and a gas from a nozzle, causing the slurry and the gas to collide with each other outside the nozzle, and depositing the particles of the layered material on a substrate to form the film. A concentration of the particles of the layered material in the slurry may be 30 mg/mL or more.

A silver-coated resin particle including a heat-resistant resin core particle and a silver coating layer formed on the surface of the resin core particle. The average grain diameter of the resin core particle is 0.1 to 10 μm, the amount of silver contained in the silver coating layer is 60 to 90 parts by mass, relative to 100 parts by mass of the silver-coated resin particle, and the exothermic peak temperature of the silver-coated resin particle by differential thermal analysis is 265° C. or higher.

A method for manufacturing a pipe type busbar includes: preparing a first tubular member made of a first material having a hollow formed therein; preparing a second tubular member having a hollow formed therein and made of a second material different from the first material; plating the first tubular member with a third material; and bonding one surface of the first tubular member and one surface of the second tubular member. The pipe type busbar manufactured thereby has the features capable of reducing a weight and a cost by a heterogeneous material, a pipe shape, and exposing a part of a copper material.

An opto-electrical cable may include an opto-electrical cable core and a polymer layer surrounding the opto-electrical cable core. The opto-electrical cable core may include a wire, one or more channels extending longitudinally along the wire, and one or more optical fibers extending within each channel. The opto-electrical cable may be made by a method that includes providing a wire having a channel, providing optical fibers within the channel to form an opto-electrical cable core, and applying a polymer layer around the opto-electrical cable core. A multi-component cable may include one or more electrical conductor cables and one or more opto-electrical cables arranged in a coax, triad, quad configuration, or hepta configuration. Deformable polymer may surround the opto-electrical cables and electrical conductor cables.

Disclosed are transparent conductors comprising a substrate, and a conductive layer formed on the substrate, wherein the conductive layer comprises a first conductive medium comprising a plurality of metal nanowires, and a second conductive medium comprising a plurality of conductive nanoparticles, and methods for forming the same.

The present disclosure describes methods of manufacture and implementations of hybrid separators for data cables having conductive and non-conductive or metallic and non-metallic portions, and data cables including such hybrid separators. A hybrid separator comprising one or more conductive portions and one or more non-conductive portions may be positioned within a data cable between adjacent pairs of twisted insulated and shielded or unshielded conductors so as to provide physical and electrical separation of the conductors. The position and extent (laterally and longitudinally) of each conductive portion and each non-conductive portion may be selected for optimum performance of the data cable, including attenuation or rejection of cross talk, reduction of return loss, increase of stability, and control of impedance.

The present invention relates to a detection device for detecting a position of a conductor, a wire processing equipment, and a method for detecting a position of a conductor in wire processing. The detection device has: a bracket; and a plurality of conductive probes provided on the bracket and spaced from each other. The conductive probes have a detection position, and the detection device is configured to determine whether the detected conductor is at a predetermined position by detecting whether the conductive probes at the detection position are electrically connected through the conductor; when at least two conductive probes are electrically connected with each other through the detected conductor, the detected conductor is determined in the predetermined position; when no two conductive probes are electrically connected with each other through the detected conductor, the detected conductor is determined not in the predetermined position. The detection device for detecting the position of the conductor, the wire processing equipment and the method for detecting the position of the conductor in the wire processing of the invention can automatically detect whether the conductor is in the designated position, which provides a basis for further automatic processing of the wire.

The present invention relates to methods of preparing nanowire networks, as well as to nanowire networks prepared thereby. The method comprises (a) providing a substrate coated with a film of a first polymer; (b) depositing nanofibers of a second polymer onto the film to form a patterned layer comprising a nanofibre network structure; (c) depositing a layer of a first metal onto the patterned layer; (d) performing a solvent development step to selectively remove the nanofibers leaving a negative pattern exposing the first polymer film; (e) performing an etching step to remove the exposed polymer film; (f) depositing a second metal or oxide thereof onto the negative pattern to form a tem plated nanowire network; and (g) performing a lift-off step to expose the nanowire network.

A Metal-Clad (MC) cable assembly is provided. In one approach, the MC cable assembly includes a core having a plurality of conductors laid parallel to one another, each of the plurality of conductors including an electrical conductor and insulation, with or without a jacket layer. The MC cable assembly further includes a metal sheath disposed over the core. In some approaches, the MC cable assembly further includes an assembly tape disposed around the plurality of conductors. In some approaches, the MC cable assembly further includes a subassembly having a set of conductors, and an assembly jacket layer disposed over the subassembly. In some approaches, a polymeric protective layer is provided over an insulation layer of one or more of the plurality of conductors and the subassembly. In some approaches, a bonding/grounding conductor may also be cabled with the plurality of conductors.