Methods and systems are provided for an electrical system of a vehicle. In one example, the system may include a first electrical device and a second electrical device that moves relative to the first electrical device. The second electrical device may be coupled to the first electrical device by an electrical conduit formed of one or more plate conductors connected in series by a coupler configured to enable pivoting of the one or more plate conductors.

A wiring member includes: a wire-like transmission member; a first sheet to which the wire-like transmission member is fixed; and a second sheet, at least a part of which is overlapped with the first sheet, wherein a first through hole is formed in one of the first sheet and the second sheet, a second through hole formed to be continuous with the first through hole and smaller than the first through hole is formed in another one of the first sheet and the second sheet.

A wiring member includes: a wiring body including a wire-like transmission member and a sheet to which the wire-like transmission member is fixed; a cover that covers the wiring body; and a buffer member, in which the wire-like transmission member includes a transmission wire body and a coating layer that covers the transmission wire body, the cover is a member harder than the coating layer, and the buffer member is provided at at least one end of the cover, and is disposed between the wire-like transmission member and the cover.

A wiring member includes: a wiring body including a wire-like transmission member and a sheet to which the wire-like transmission member is fixed; a cover that covers the wiring body; and a buffer member, in which the wire-like transmission member includes a transmission wire body and a coating layer that covers the transmission wire body, the cover is a member harder than the coating layer, and the buffer member is provided at at least one end of the cover, and is disposed between the wire-like transmission member and the cover.

The present disclosure provides a flexible flat cable manufacturing method and a flexible flat cable. The steps of the manufacturing method are firstly obtaining a conductor, secondly doping a granule made of fluororesin into a resin to produce a mixed resin and the mixed resin is covering the periphery of the conductor, finally covering the periphery of the mixed resin with a plastic film layer. The flexible flat cable can be produced according to the method, in which the mixed resin layer doped with fluororesin granules could lower the dielectric constant and dielectric loss to lower the influence to the conductor from the mixed resin layer. The fluororesin is flame retardant, heat resistant, and corrosion resistant, which reduces the use of flame retardants.

The present disclosure provides a flexible flat cable manufacturing method and a flexible flat cable. The steps of the manufacturing method are firstly obtaining a conductor, secondly doping a granule made of fluororesin into a resin to produce a mixed resin and the mixed resin is covering the periphery of the conductor, finally covering the periphery of the mixed resin with a plastic film layer. The flexible flat cable can be produced according to the method, in which the mixed resin layer doped with fluororesin granules could lower the dielectric constant and dielectric loss to lower the influence to the conductor from the mixed resin layer. The fluororesin is flame retardant, heat resistant, and corrosion resistant, which reduces the use of flame retardants.

There are provided a conductor for busbar electric wire, and a busbar electric wire configured by a conductive plate material having a substantially rectangular cross-sectional shape, the conductor including: an opening formed on one side in a width direction orthogonal to a longitudinal direction of the plate material, the width direction corresponding to a planar direction of the plate material.

There are provided a conductor for busbar electric wire, and a busbar electric wire configured by a conductive plate material having a substantially rectangular cross-sectional shape, the conductor including: an opening formed on one side in a width direction orthogonal to a longitudinal direction of the plate material, the width direction corresponding to a planar direction of the plate material.

An electro-optic element comprises a first substrate; a second substrate generally parallel to the first substrate; a first bus having a first bus segment disposed on an inner surface of the first substrate and extending along a first portion of a perimeter of the first substrate and a second bus segment disposed on an inner surface of first substrate and extending along a second portion of the perimeter of the first substrate. The second bus segment is in a spaced apart relationship with first bus segment. A second bus has a third bus segment and a fourth bus segment is disposed on the second substrate, each extending along a portion of the perimeter of the second substrate. A controller is configured to be in selective electrical communication with first and second buses and to independently control a voltage applied to each of the bus segments.

In general, the application of the present invention regards the electrical wiring of buildings. In particular, the solution identified concerns the positioning and installation of boxes suitable for housing electrical sockets, or control systems, or various sensors on the walls of the rooms, when these internal walls are made, or covered, with panels made of plasterboard or, alternatively, with other similar materials.

The present invention indicates a box for extracting electrical contacts from an electric line made by means of a “ribbon cable” laid under a surface finishing panel of a wall or ceiling. This box is easy to install, and makes an electrical power interface available on this wall, so that said power interface is accessible to a load.