An electric pulse decomposition method for separating a composite material by an electric pulse, the composite material being obtained by bonding or joining a plurality of conductors to each other with an insulating member, the electric pulse decomposition method including a protrusion formation step for forming a protrusion in a specific site, on a side on which the composite material is arranged, of at least one of the plurality of conductors, and a separation step for separating the plurality of conductors in the composite material 1 by respectively bringing electrodes into contact with surfaces of the plurality of conductors and applying an electric pulse between the electrodes to destroy the insulating member. This makes it possible to separate the plurality of conductors from the composite material by making a shock wave caused by a current of the dielectric breakdown functioning as an adhesive to effectively destroy the insulating member.

Provided are a receive cable and a medical image diagnostic system capable of reducing the burden on imaging staff. A receive cable includes: a coaxial cable; a tubular shield conductor accommodating the coaxial cable and having at least one non-conductive cutout portion at an intermediate portion in the axis direction; and a tubular conductor overlapping with the cutout portion and a part of each of two shield conductors located on both sides of the cutout portion, and is disposed with respect to the shield conductor via a gap portion in the diameter A direction of the shield conductor.

Provided are a receive cable and a medical image diagnostic system capable of reducing the burden on imaging staff. A receive cable includes: a coaxial cable; a tubular shield conductor accommodating the coaxial cable and having at least one non-conductive cutout portion at an intermediate portion in the axis direction; and a tubular conductor overlapping with the cutout portion and a part of each of two shield conductors located on both sides of the cutout portion, and is disposed with respect to the shield conductor via a gap portion in the diameter A direction of the shield conductor.

An in-vehicle communication system includes a transmitter that transmits a differential signal, a receiver that receives the differential signal, and a communication cable that connects between the transmitter and the receiver and transmits the differential signal. The communication cable includes a twisted wire, a sheath covering the twisted wire, and a talc layer provided between the twisted wire and the sheath. The sheath includes a pair of ribs located across a straight line connecting a conductor center of a first coated wire and a conductor center of a second coated wire in a transverse section of the communication cable. The talc layer is provided along the surface of the twisted wire.

An in-vehicle communication system includes a transmitter that transmits a differential signal, a receiver that receives the differential signal, and a communication cable that connects between the transmitter and the receiver and transmits the differential signal. The communication cable includes a twisted wire, a sheath covering the twisted wire, and a talc layer provided between the twisted wire and the sheath. The sheath includes a pair of ribs located across a straight line connecting a conductor center of a first coated wire and a conductor center of a second coated wire in a transverse section of the communication cable. The talc layer is provided along the surface of the twisted wire.

A wiring harness 10 according to one aspect of the present disclosure includes a plurality of wires (20) and an exterior member (40) for covering the plurality of wires (20). The exterior member (40) includes a tape member (41) to be wound to bundle the plurality of wires (20). The wiring harness (10) includes a tape cutting wire (50) provided such that an intermediate part in a length direction is covered by the tape member (41), and the tape cutting wire (50) is capable of cutting the tape member (41) by an end part (51) in the length direction being pulled.

A wiring harness 10 according to one aspect of the present disclosure includes a plurality of wires (20) and an exterior member (40) for covering the plurality of wires (20). The exterior member (40) includes a tape member (41) to be wound to bundle the plurality of wires (20). The wiring harness (10) includes a tape cutting wire (50) provided such that an intermediate part in a length direction is covered by the tape member (41), and the tape cutting wire (50) is capable of cutting the tape member (41) by an end part (51) in the length direction being pulled.

An insulated wire includes a core body comprising electrically-conductive material. The insulated wire also includes a permanent coating comprising electrically-insulating material and disposed on the core body to electrically insulate the core body. The insulated wire further includes a removable coating disposed on the permanent coating to provide the core body and the permanent coating with structural support during cutting of the core body and the permanent coating to the desired length.

An insulated wire includes a core body comprising electrically-conductive material. The insulated wire also includes a permanent coating comprising electrically-insulating material and disposed on the core body to electrically insulate the core body. The insulated wire further includes a removable coating disposed on the permanent coating to provide the core body and the permanent coating with structural support during cutting of the core body and the permanent coating to the desired length.

An in-vehicle communication system includes a transmitter that transmits a differential signal, a receiver that receives the differential signal, and a communication cable that connects between the transmitter and the receiver and transmits the differential signal. The communication cable includes a twisted wire, a sheath covering the twisted wire, and a talc layer provided between the twisted wire and the sheath. The sheath includes a pair of ribs located across a straight line connecting a conductor center of a first coated wire and a conductor center of a second coated wire in a transverse section of the communication cable. The talc layer is provided along the surface of the twisted wire.