A wire harness according to one aspect of the present disclosure includes: a first wire harness that includes a first electric wire, a first shielding member, and a first connector; a second wire harness that includes a second electric wire, a second shielding member, and a second connector; and a connection member that electrically connects a drain wire of the first shielding member and a drain wire of the second shielding member to each other. A drain wire drawn out from an end portion of the first shielding member on the first connector side is grounded. A drain wire drawn out from an end portion of the second shielding member on the second connector side is inserted into a vacant cavity of the second connector.

A wire harness includes an electric wire, a braided conductor covering the electric wire, a grommet having a tubular insertion portion through which the electric wire and the braided conductor are inserted, a water stop sheet sandwiched between an inner peripheral surface of the insertion portion and the braided conductor, and a fixture attached to the insertion portion so as to reduce a diameter of the insertion portion. The water stop sheet includes a base material layer having a plurality of pores communicating with each other in a thickness direction of the water stop sheet and a sealing compound layer laminated on the base material layer. The sealing compound layer is deformed so as to enter gaps between thin conductor wires constituting the braided conductor and the pores of the base material layer.

A jacket for an elongated assembly is disclosed. The jacket, which may be a tubular shape or sheet, comprises a film layer to surround a core member of the elongated assembly, wherein the film layer has a first surface to be arranged abutting the core member in a non-bonded relationship; a braided, woven, or warp-knit layer comprising high-melt filament having a titer from 30 to 800 denier; and a bonding region between the braided, woven, or warp-knit layer and a second surface of the film layer, opposing to the first surface, to adhere at least a portion of the high-melt fibers. The jacket may further comprise an inner film layer in a non-bonded relationship with the film layer.

A cable in which decrease in a shield performance of a shield layer due to bending or twisting is difficult to occur is provided. A cable includes: a cable core including one or more electrical wires; a shield layer made of a metallic wire arranged on a periphery of the cable core; and a sheath arranged on a periphery of the shield layer, the metallic wire is made of a copper alloy wire made of a copper alloy containing indium, a content of which is equal to or more than 0.3 mass % and equal to or less than 0.65 mass %, and the metallic wire has tensile strength that is equal to or higher than 350 MPa and elongation that is equal to or higher than 7%.

A cable includes: plural cable sets each including a pair of core wires, a shielding layer covering the pair of core wires, and an outer layer covering the shielding layer; and plural fixing wires cross-braided outside the cable sets to keep the cable sets in a row position along a lateral direction.

A cable shielding and an electrical conductor having such a cable shielding are provided. The cable shielding has a first wire winding and a second wire winding. The first wire winding has a plurality of turns. The first wire winding is wound in a first direction with a first pitch about a longitudinal axis. The second wire winding has a plurality of turns. The second wire winding is wound in a second direction, which is different from the first direction, with a second pitch about the longitudinal axis. Turns of the plurality of turns of the first wire winding and corresponding turns of the plurality of turns of the second wire winding cross one another in each case at a first crossing point in such a way that a plurality of first crossing points of the first wire winding and the second wire winding are present in the direction of the longitudinal axis. The plurality of first crossing points run at least approximately helically in the direction of the longitudinal axis.

A harness assembly may include a cable having a cable shielding around at least a portion of a plurality of wires, a connector with an integrated backshell arranged at an angle with respect to the cable, an external braid disposed around at least a portion of the backshell and the cable, and an overbraid around at least a portion of the external braid, the overbraid having two layers.

A flex-resistant shielded composite cable includes a plurality of electric wires, a shielding layer and a tubular sheath. Each of the electric wires includes a conductor part which is composed of a twisted wire, which is formed by twisting a plurality of strands having a diameter of 0.05 mm or more and 0.12 mm or less, a nominal sectional area of the conductor being 8 sq or more, a covering part covering the conductor part. The shielding layer is formed of a braid formed by braiding plated fiber formed by performing metal-plating on anti-tension fiber and covers outer periphery of the plurality of electric wires. The tubular sheath is provided on the outer periphery of the shielding layer and made of an insulating resin.

The objective of the present invention is to prevent a deterioration in communication performance A shielded electrically conductive path (A) is provided with a shielded terminal (25) including an inner conductor (26), and an outer conductor (28) enclosing the inner conductor (26), a shielded electric cable (10) including a core wire (12) affixed to a rear end portion of the inner conductor (26), a braided wire (15) enclosing the core wire (12), and a sheath (18) enclosing the braided wire (15), and a sleeve (20) attached to the outer circumference of a front end portion of the sheath (18), wherein, in the front end portion of the shielded electric cable (10): the braided wire (15) extending from a front end (18F) of the sheath (18) is folded back toward the rear to cover the outer circumference of the sleeve (20); a crimping portion (30) of the rear end portion of the outer conductor (28) is crimped to the sleeve (20) while enclosing the outer circumference of a folded back portion (17) of the braided wire (15); and a front end (20F) of the sleeve (20) is positioned forward of the front end (18F) of the sheath (18) in the front-rear direction.

A multi-core cable includes a plurality of coaxial wires, each coaxial wire including a center conductor whose sectional area is 0.0005 mm.sup.2 to 0.0039 mm.sup.2. The multi-core cable includes a resin tape wrapped around the coaxial wires so that all of the plurality of coaxial wires are included therein, a shield layer being made of metal and covering the resin tape, and a sheath covering the shield layer and arranged at an outermost layer of the multi-core cable. The sheath is made of thermoplastic vulcanizate or tetrafluoroethylene-propylene-based fluorine containing rubber.