Provided are a drawing creation method, a wire harness manufacturing method, and a drawing creation device. A drawing showing a wire harness is created by the drawing creation method. The wire harness is configured with wires bundled together. The wire harness includes wire branch points and branch lines. The drawing is created based on information including following (1) to (3) and at least one of following (4) or (5): (1) a path of the wire harness in a movable body, (2) a distance between path branch points where the path branches, (3) a length from each path branch point to a corresponding connection target of the wire harness, (4) identification information of the connection target of the wire harness, (5) identification information of the connection target of each wire. The drawing reflects a distance between the wire branch points and a length of each branch line.

A tool for fixing a protective textile sleeve about an elongate member contained therein and method of use thereof is provided. The tool includes a clamp assembly having opposed clamp members attached to one another for pivotal movement relative to one another between an open state and a closed state. The clamp members have clamping surfaces, wherein at least one of the clamping surfaces has at least one outlet. A fluid source is arranged in fluid communication with the at least one outlet, and a heat source is configured to heat fluid from the fluid source to create steam. The steam is dispensed outwardly from the at least one outlet to cause an adhesive on the sleeve to become activated to bond with an adjacent abutting surface.

A cable (1) assembly device for producing cabling including: a support surface (2) on which the cable assembly is carried out (1), cable (1) fastening and guide elements (3), said fastening and guide elements (3) comprising a vacuum element for joining it to said support surface (2), a feeder (4) of the cable to be assembled, a computation means that includes a cabling diagram in its memory and the location of the fastening and guide elements (3) on the support surface (2), a storage module (5) for cable (1) fastening and guide elements (3), positioning means (6) of the fastening and guide elements (3) on the support surface (2).

A composite harness includes a composite cable that includes a plurality of first electric wires, a multicore wire formed by covering a plurality of second electric wires having a smaller diameter than the plurality of first electric wires with one urethane-based resin inner sheath to be in contact with the first electric wires, and a jacket covering an outer periphery of the plurality of first electric wires and the multicore wire, and a molded resin provided at an end portion of the composite cable so as to cover an outer surface of the inner sheath at an end portion of the multicore wire. The outer surface of the inner sheath is irregularity-formed at least at a portion in contact with the plurality of first electric wires and a portion covered with the molded resin.

A system for the automated production of a cable set, which has a branched structure of a plurality of individual line elements. In a modular set-up in the first part, a plurality of first processing stations, and in the second part, a plurality of second processing stations are arranged. In the first part, there is an automatic preparation of the individual line elements, which are then collected in a buffer station at the end of the first part. In the second part, the prepared individual line elements are assembled into the cable set. The line elements are plugged into connector casings in a connector station and transferred to second transporters, and via which the branched structure of the cable set is then formed by moving along second tracks. In this spread-out branched structure, a fixing of the line elements to one another takes place in a fixing station.

A system for the automated manufacture of a wiring harness, which demonstrates a branched structure made up of multiple individual conductor elements. To form wiring harnesses having an individually branched structure, the conductor elements are automatically brought into a predefined distribution structure, multiple second rails oriented in parallel to each other and multiple second transporters, distributed on the second rails, being used for this purpose. The second transporters are each fitted with one wire end of the conductor elements. To form the distribution structure, the second rails are subsequently moved in a vertical direction, and the second transporters are moved along the second rail. In this spread-apart structure, additional processing steps are carried out, for example a fixing of the conductor elements to each other.

A computerized discrete wire inventory indexing system organizes and automates the intake of wiring used in a wire harness assembly work cell. Functions in a work cell may be duplicated into a second arrangement symmetrically opposite to a first arrangement so that an indexing system in accordance with the invention may operate between or alongside the adjacent work cells to execute its tasks in tandem and produce pairs of wires to be used within the two work cells. The wire indexing system operates with a tandem wire pulling machine on a movable shuttle that grabs pairs of wires from the indexing system and draws them to length. Both the shuttle and the wire indexing system may includes fixtures for stripping and terminating wires by crimping terminals onto prepared wire ends. Computer control enables rapid and correct wire production and efficient process change-overs.

An electric wire conductor having both flexibility and a space-saving property, a covered electric wire, and a wiring harness containing such an electric wire conductor. The electric wire conductor contains a plurality of elemental wires, and has a flat portion in which a cross-section intersecting an axial direction of the wire strand has a flat shape. In the cross-section of the flat portion, a vacancy ratio defined as a ratio of vacancies not occupied by the elemental wires is 17% or higher. Further, a covered electric wire contains the electric wire conductor and an insulator covering the electric wire conductor. Furthermore, a wiring harness contains the covered electric wire.

A distribution member includes plural electric wire pairs each including a pair of electric wires, a first fixing member integrally fixing the electric wire pairs, and a second fixing member that is separated from the first fixing member and integrally fixes electric wires of at least one of the electric wire pairs. The first fixing member and the second fixing member each include a holder holding the electric wires and a resin mold part that includes a molding resin and is molded so as to cover a part of the electric wire pairs held by the holder. The holder includes at least one interposed part that is interposed between the held electric wires. The distribution member further includes a combining part that is integrally formed with the holders of the first and second fixing members and combines the holders of the first and second fixing members.

The invention relates to a method for producing an adhesive tape, in particular a wrapping tape for wrapping around cables in automobiles. A strip-shaped carrier (2) is provided with a UV cross-linkable adhesive coating (5). In addition to an acrylate-based pressure-sensitive adhesive with embedded photoinitiators, the adhesive coating (5) comprises at least one additive. The photoinitiators are activated for cross-linking by irradiation with a UV light source (6) emitting in the range of its activation wavelength. According to the invention, the activation wavelength of the photoinitiators is above 280 nm, in particular above 315 nm.