A wire harness includes a plurality of insulated electric wires, a sheath covering a part in a longitudinal direction of the insulated wires, and a branching portion fixing member covering an end portion of the sheath with the insulated wires guided out therefrom, and one-parts in respective longitudinal directions of the insulated wires being guided out from the end portion of the sheath. The branching portion fixing member includes a plurality of guiding-out portions to guide out the one-parts of the plurality of insulated wires respectively. The wire harness is provided with a protective tube to cover at least one of the guiding-out portions, and the insulated wire guided out from the at least one of the guiding-out portions, and a tightening member to tighten and fix one end portion of the protective tube to an outer peripheral surface of the at least one of the guiding-out portions.

A method for the application of a tubular hull (120) to an electric cable (100) is provided. The tubular hull (120) comprises a plurality of ring-shaped elements (102) and/or of tube-shaped elements (101). The method comprises at least the following steps: a.) pre-arranging a part of the tubular hull (120) by means of a tubular hull application unit (200); b.) inserting the electric cable (100) into the tubular hull application unit (200) and into the pre-arranged part of the tubular hull (120); c.) removing the electric cable (100) from the tubular hull application unit (200); and x.) repeating steps a.), b.) and c.) at least two times and in consecutive order. Furthermore, a tubular hull application unit adapted for carrying out such a method and a tether produced according to this method and comprising an electric cable and a tubular hull are provided.

An object is to suppress concentration of stress on electrical wires when the electrical wires are bent in the vicinity of a bracket. A bracket-equipped conductive path includes a conductive path main body that is constituted by a plurality of coated wires, a protector that surrounds the conductive path main body, and a bracket that is made of metal and includes a base portion that is embedded in the protector in such a manner that detachment of the base portion from the protector is restricted and an attachment portion that extends from the base portion. The base portion has a flat plate shape and is arranged to face the conductive path main body in a direction that is substantially parallel to a thickness direction of the base portion.

Providing an outer cover body for electrical wires that can improve the degree of freedom of design while preventing anisotropy in mechanical properties and also make it possible to form even a compact outer cover body for electrical wires. An outer cover body for electrical wires that is to be attached to the outer periphery of an electrical wire, the outer cover body for electrical wires being formed of a bent thermoplastic resin foam sheet having a density of not less than 200 Kg/m.sup.3 and not more than 700 Kg/m.sup.3.

An apparatus for wearing a power cord includes an elongate power cord having a length that extends from a first end having a power connector to a second end having a device connector. The apparatus also includes an elastic component and a housing for holding the power connector and the device connector therein. The apparatus has a wearing configuration and a charging configuration. In the wearing configuration, the device connector and the power connector are disposed in the housing and the apparatus is secured to the user. In the charging configuration, the device connector extends out of the housing and connects to a portable electronic device, and the power connector extends out of the housing and connects to a power supply. In another embodiment, the power cord has a power bank on a first end of the cord rather than a power connector. The power bank is stored inside the housing.

An apparatus for wearing a power cord includes an elongate power cord having a length that extends from a first end having a power connector to a second end having a device connector. The apparatus also includes an elastic component and a housing for holding the power connector and the device connector therein. The apparatus has a wearing configuration and a charging configuration. In the wearing configuration, the device connector and the power connector are disposed in the housing and the apparatus is secured to the user. In the charging configuration, the device connector extends out of the housing and connects to a portable electronic device, and the power connector extends out of the housing and connects to a power supply. In another embodiment, the power cord has a power bank on a first end of the cord rather than a power connector. The power bank is stored inside the housing.

A signal line protection assembly of an aerial vehicle includes a foot stand and a protection sleeve. The foot stand includes a foot stand sleeve and a lower cover including an antenna compartment configured to receive an antenna of the aerial vehicle. The protection sleeve is configured to receive a signal line. At least a portion of the protection sleeve is received in the foot stand sleeve. The signal line includes a data line for the antenna.

Provided are: a joining structure making it possible to join resin plates together without needing to provide a surplus resin plate section for joining, and offering excellent workability in the joining together of resin plates; a method of producing same; and a wire exterior cover using the joining structure. A joining structure 1 comprises a joining part 10 formed by butt-welding a plate surface part 22 of a first resin plate 21 made of a first resin, and an end surface part 24 of a second resin plate 23 made of a second resin. In the joining structure, a foam resin is used for the first resin and a foam resin or a non-foam resin is used for the second resin. The joining part 10 has a welding recess 25 in a surface 22a of the plate surface part 22. In an internal corner 10a of a reverse surface 22b, there is a padding section 27 formed by melt-flowing and solidifying of at least the first resin out of the first resin and the second resin.

A flexible innerduct structure having a first margin region, a second margin region, and a middle region, where the middle region is located between the first and second margin regions. The innerduct structure contains at least two flexible, longitudinal chambers, with each chamber being designed for enveloping at least one cable. The flexible innerduct structure contains at least one strip-shaped textile, each strip containing a first side and a second edge and extending in the longitudinal direction. All first and second edges of the strips are located in the middle region and each strip-shaped textile extends outwards from the middle region, folds about a fold axis located in either the first or second margin region and returns to the middle region. At least one strip extends from the first to the second margin region and the strips are attached together in the middle region.

A waterproof structure of a multicore cable includes: a multicore cable in which a power line and a signal line are surrounded by a sheath; a heat-shrinkable tube having a sheath covering portion that covers the sheath and an electric wire covering portion that is continuous with the sheath covering portion and covers the power line and the signal line led out from a front end of the sheath; a waterproof portion that is disposed in a gap between the electric wire covering portion and the power line and the signal line to prevent water from entering the gap between the electric wire covering portion and the power line and the signal line; and a protector that holds the heat-shrinkable tube therein and has a stopper located near a front end of the heat-shrinkable tube.