A feed-through provides electromagnetic shielding where one or more signal leads pass through an enclosure. It comprises a frame, having at least one opening, and an assembly comprising two or more joining parts, forming one or more elongated waveguides. The joining parts are divisible along the length of the waveguides, thereby being capable of surrounding a signal lead. The assembly is adapted to be attached to the frame such that one or more signal leads can pass through an opening in the frame and through one of the waveguides. Installation is of the feed-through is made easier by the opening in the frame having a larger maximum extension than the maximum extension of a waveguide.

A cable includes: a signal core module including a pair of inner conductors and an inner insulative layer enclosing the inner conductors, the inner conductors extending parallel to each other, the inner insulative layer forming a spacing region between said inner conductors; a grounding core arranged beside the signal core module; and a metal shielding layer enclosing the signal core module and the grounding core.

A shielded conductive path capable of being easily managed in terms of a length of a portion of a single core wire protruding from a shield pipe includes a shield pipe electromagnetically shielding a plurality of single core wires inserted therein and a spacer having insertion holes individually receiving the single core wires. Each single core is made of a single conductor as a core wire. The spacer is fitted inside of the shield pipe while being restricted from displacement in directions perpendicular to an axial direction of the shield pipe.

A helically wound insulated twinax cable reduces cable dielectric loss by increasing the percentage of air in the dielectric filler surrounding the signal conductors. The helical insulator wire winding further provides mechanical support and reduces the risk of creating an electrical short-circuit. This will improve differential signaling capability of the two-conductor cable and enable longer cable range.

Provided is a cable including: at least two signal cables formed of first and second signal cables for differential transmission; a third cable for ground; a fourth cable for power supply; a metal sheet adapted to cover the first and second signal cables; a coating material adapted to house the first and second signal cables covered with the metal sheet, and the third and fourth cables; and a magnetic powder-mixed resin filled into an inner space of the coating material and prepared by mixing magnetic powder with a resin.

Disclosed is a high-frequency cable, in particular, a high-frequency cable with a stable structure, including: two signal cables arranged in parallel; one ground cable located between the two signal cables or two ground cables respectively located on lateral sides of the two signal cables, and axes of the two signal cables and axes of the two ground cables being located on the same plane; a fastening layer wrapped outside the two signal cables and the ground cable, and configured to fasten the two signal cables and the ground cable; a shielding layer wrapped outside the fastening layer; and a sheath layer wrapped on the shielding layer. The high-frequency cable with a stable structure provided by the present disclosure features a stable structure, is easy to process, reduces production costs, and provides good electrical performance.

A protective device to be integrated into a high-voltage cable of a high-voltage on-board power supply includes a cut-out for interrupting at least one electrical conductor of the high-voltage cable in a fault scenario, a shielding element for forming a cable shield with a shielding conductor of the high-voltage cable, and a housing to be arranged between two high-voltage-cable sections of the high-voltage cable. In the housing, the cut-out and the shielding element are arranged, and the housing has contacts for connecting the cut-out to conductor sections of the at least one conductor and for connecting the shielding element to shielding-conductor sections of the shielding conductor. At least a part of the housing is capable of being non-destructively detached from the high-voltage-cable sections, in order to enable an exchange of at least the cut-out in the case of a defect of the cut-out.

A shield wire is formed of eight twisted insulated core wires 1, an inclusion 2 between these respective insulated core wires 1, a tape 3 laterally wound around an outer periphery of a core formed of the insulated core wires and inclusion, a drain wire 4 disposed on an outer surface of the tape, a conductive fiber braided body 5 formed on an outer peripheral surface of the tape so as to interpose the drain wire, a sheath 6 that forms an outer peripheral surface of the braided body, and an adhesive layer 7 between the braided body and sheath. A braided body 5′ is adhesively integrated to the sheath 6′ by an adhesive layer; thus, the braided body 5′ is stripped with the sheath. This eliminates a need for a removal work of the braided body after stripping the sheath, thus ensuring good workability of the terminal processing.

A shielded cable includes signal wires each having a signal conductor covered by an insulator, and a shield conductor comprising a metal foil resin tape spirally and overlappingly wrapped around the two signal wires, wherein an edge portion of the metal foil resin tape is folded back so that the metal foil therein is oriented outward, thereby bringing metal foils, which are arranged on lower and upper sides in the overlapping part of wrapping of the metal foil resin tape, into electrical contact with each other. The shielded cable includes two drain wires provided outside the metal foil resin tape and configured to be in electrical contact with an exposed part of the outwardly folded-back metal foil, which is exposed out of the overlapping part.

A coaxial cable of the present invention comprises a center conductor, a dielectric surrounding the center conductor, a shielding tape surrounding the dielectric, a braided metal surrounding the shielding tape, and an outer jacket surrounding the braided metal. The shielding tape comprises: (i) a first shielding layer bonded to a first separating layer; (ii) a second shielding layer bonded to the first separating layer and a second separating layer; and (iii) a third shielding layer bonded to the second separating layer. The present invention eliminates the potential problem of the outer shielding structures separating and interfering with connector attachment. Furthermore, the use of three or more shielding layers in the shielding tape of the present invention improves the flex life of the shield tape by covering micro-cracks in the metal layers with additional shielding layers, thus reducing signal egress or ingress. Accordingly, the present invention provides cost savings and/or an improvement in shielding performance.