A complex harness includes first electric wires, each of which includes a first center conductor and a first insulation that covers the first center conductor, a cable including second electric wires, each of which includes a second center conductor and a second insulation that covers the second center conductor, and an inner sheath that covers the second electric wires, and an outer sheath covering the first electric wires and the cable collectively. The first electric wires are extended from an end of the outer sheath. The cable is extended from the end of the outer sheath in a state where the second electric wires are collectively covered by the inner sheath in such a manner that an extension length of the cable from the end of the outer sheath is greater than an extension length of the first electric wires from the end of the outer sheath.

A harness for a vehicle, configured to be attachable to a vehicle body, includes a cable including a plurality of electric wires, each of which includes a center conductor and an insulation that covers the center conductor, a separator including a paper, a non-woven fabric, or a resin tape that covers and contacts with the plurality of electric wires, and an outer sheath that covers the separator, a rubber member provided along a longitudinal direction of a part of the cable, and a fixing member for attaching the cable to the vehicle body. The fixing member is attached to an outer surface of the outer sheath through the rubber member.

A harness for a vehicle, configured to be attachable to a vehicle body, includes a cable including a plurality of electric wires, each of which includes a center conductor and an insulation that covers the center conductor, a separator including a paper, a non-woven fabric, or a resin tape that covers and contacts with the plurality of electric wires, and an outer sheath that covers the separator, a rubber member provided along a longitudinal direction of a part of the cable, and a fixing member for attaching the cable to the vehicle body. The fixing member is attached to an outer surface of the outer sheath through the rubber member.

A protective textile sleeve having enhanced end fray resistance and being adapted to be bonded to an elongate member extending therethrough, and method of construction thereof, are provided. The sleeve has a wall with a cavity bounded by an innermost surface extending between opposite open ends. A first material, including a hot melt adhesive material, facilitating bonding the wall to an outer surface of an elongate member extending therethrough, is bonded to the wall immediately adjacent the opposite ends, and a second material, facilitating prevention of end fray of the wall ends, including an elastomeric material is bonded to the wall immediately adjacent the opposite ends.

A protective textile sleeve having enhanced end fray resistance and being adapted to be bonded to an elongate member extending therethrough, and method of construction thereof, are provided. The sleeve has a wall with a cavity bounded by an innermost surface extending between opposite open ends. A first material, including a hot melt adhesive material, facilitating bonding the wall to an outer surface of an elongate member extending therethrough, is bonded to the wall immediately adjacent the opposite ends, and a second material, facilitating prevention of end fray of the wall ends, including an elastomeric material is bonded to the wall immediately adjacent the opposite ends.

Disclosed is a Multi-Use Dust Mitigation System (MDMS). The MDMS includes a finger section, a hand section physically attached to the finger section, a fabric-material within both the finger section and hand section, a plurality of conductive-fibers within the fabric-material, and a plurality of input-nodes approximately adjacent to the fabric-material. The fabric-material includes a front-surface and a back-surface. The plurality of conductive-fibers are approximately parallel along the fabric-material and are approximately adjacent to the front-surface of the fabric-material. The plurality of input-nodes are in signal communication with the plurality of conductive-fibers and configured to receive an alternating-current (AC) voltage-signal from an input-signal-source and the plurality of conductive-fibers are configured to generate an electric-field on the front-surface of the fabric-material in response to the plurality of input-nodes receiving the AC voltage-signal from the input-signal-source.

Disclosed is a Multi-Use Dust Mitigation System (MDMS). The MDMS includes a finger section, a hand section physically attached to the finger section, a fabric-material within both the finger section and hand section, a plurality of conductive-fibers within the fabric-material, and a plurality of input-nodes approximately adjacent to the fabric-material. The fabric-material includes a front-surface and a back-surface. The plurality of conductive-fibers are approximately parallel along the fabric-material and are approximately adjacent to the front-surface of the fabric-material. The plurality of input-nodes are in signal communication with the plurality of conductive-fibers and configured to receive an alternating-current (AC) voltage-signal from an input-signal-source and the plurality of conductive-fibers are configured to generate an electric-field on the front-surface of the fabric-material in response to the plurality of input-nodes receiving the AC voltage-signal from the input-signal-source.

Disclosed is a Multi-Use Dust Mitigation System (MDMS). The MDMS includes a finger section, a hand section physically attached to the finger section, a fabric-material within both the finger section and hand section, a plurality of conductive-fibers within the fabric-material, and a plurality of input-nodes approximately adjacent to the fabric-material. The fabric-material includes a front-surface and a back-surface. The plurality of conductive-fibers are approximately parallel along the fabric-material and are approximately adjacent to the front-surface of the fabric-material. The plurality of input-nodes are in signal communication with the plurality of conductive-fibers and configured to receive an alternating-current (AC) voltage-signal from an input-signal-source and the plurality of conductive-fibers are configured to generate an electric-field on the front-surface of the fabric-material in response to the plurality of input-nodes receiving the AC voltage-signal from the input-signal-source.

A conductive trace residing on a stretchable medium, whose geometry in terms of one or more of width, thickness, material stack-up, and other properties are varied along the trace to reduce changes in trace resistance when the medium is stretched. In some embodiments, the geometry is arranged to encourage increased bending in selected regions of the trace to allow stretch deformation of the trace at least partially by elongation rather than entirely by dimensional deformation, thereby reducing conductivity change due to changes in cross-sectional area.

A conductive trace residing on a stretchable medium, whose geometry in terms of one or more of width, thickness, material stack-up, and other properties are varied along the trace to reduce changes in trace resistance when the medium is stretched. In some embodiments, the geometry is arranged to encourage increased bending in selected regions of the trace to allow stretch deformation of the trace at least partially by elongation rather than entirely by dimensional deformation, thereby reducing conductivity change due to changes in cross-sectional area.