A shield foil removing device includes an opening and closing chuck configured to accommodate two wire cores surrounded by a shield foil in a space having a rectangular cross section orthogonal to an electric wire longitudinal direction, which is formed by closing, in such a direction that a longitudinal direction of the rectangular space and an arrangement direction of the two wire cores in a cross section coincide with each other, compresses the shield foil in a direction orthogonal to an arrangement direction of the two wire cores by reducing the rectangular space by a closing operation, and brings the shield foil into close contact with outer peripheral surfaces of the two wire cores to secure a gap continuous in a longitudinal direction of the shielded electric wire between both of outer peripheral curved surfaces adjacent to each other of the two wire cores and the shield foil.

A control device according to some embodiments of the disclosure includes one or more motors directed by the control device to form whip(s) from a length of a cable by causing the cutting of the cable in accordance with specifications based at least in part on whip information. An interface communicates the whip information between the control device and a user device.

An automatic-robotic-system-for-cable assembly system and method is provided. The method and system are configured to use a cartridge which holds one or both ends of the cable. The cartridge moves along an automatic cable assembly line, with the line segmented into different stages, at which a process is performed by a specific machine. Different machines, such as actuators or modular machines, perform operations on the cartridge at the different stages. In preparation for or as part of the operations, the actuators or modular machines may directly physically apply one or more forces to a cable held by the cartridge, causing the cable to spool toward or away from the modular machines.

An embedded wire removal tool is disclosed. The embedded wire removal tool can include a feed mechanism operable to cause movement of a cable. The cable can have a jacket about a core. The cable can also include a wire disposed about the core and at least partially embedded in the jacket. The embedded wire removal tool can also include a jacket cutter operable to receive the cable from the feed mechanism and remove at least a portion of the jacket. In addition, the embedded wire removal tool can include a wire excavator operable to separate the wire from the core.

A cable termination system including a power cable sequentially including a first length of exposed outer semiconductive layer, a length of exposed insulating layer and a length of exposed electric conductor, an electric field control element adapted to be arranged around a portion of said power cable, said electric field control element including: first and second longitudinally spaced semiconducting electrodes; a field grading layer longitudinally extending between the first and second semiconducting electrodes and in electric contact therewith; an insulating layer surrounding the semiconducting electrodes and the field grading layer, wherein the first semiconducting electrode is positioned across a first boundary between the first length of exposed outer semiconductive layer and the length of exposed insulating layer, wherein said second semiconducting electrode is electrically connected with said length of exposed electric conductor, a tubular insulating body adapted to house said power cable and said electric field control element.

A cable termination system including a power cable sequentially including a first length of exposed outer semiconductive layer, a length of exposed insulating layer and a length of exposed electric conductor, an electric field control element adapted to be arranged around a portion of said power cable, said electric field control element including: first and second longitudinally spaced semiconducting electrodes; a field grading layer longitudinally extending between the first and second semiconducting electrodes and in electric contact therewith; an insulating layer surrounding the semiconducting electrodes and the field grading layer, wherein the first semiconducting electrode is positioned across a first boundary between the first length of exposed outer semiconductive layer and the length of exposed insulating layer, wherein said second semiconducting electrode is electrically connected with said length of exposed electric conductor, a tubular insulating body adapted to house said power cable and said electric field control element.

The present disclosure relates to the field of cable processing apparatus and discloses a cable radial cutting system and a reaction force cone processing apparatus with the cable radial cutting system. The cable radial cutting system includes a cutting bracket, a planetary gear set, a first driving piece and a second driving piece which are mounted on the cutting bracket, and a cutting tool driven by the planetary gear set to rotate and move radially, where the first driving piece and the second driving piece jointly drive the planetary gear set to rotate.

The invention relates to an adapter device (10, 110, 210) for positioning at least one conductor (68), such as a conductor pair, for example, of a cable (70) to be measured, which adapter device comprises a receiving device (12) and a holding clamp (14) which can be attached to the receiving device (12). Attaching the holding clamp (14) to the receiving device (12) fixes the holding clamp (14) in position and alignment relative to the receiving device (12). The holding clamp (14) is designed to receive and clamp the at least one conductor (68) of the cable (70) to be measured in sections in order to fix said cable in the position and alignment thereof relative to the holding clamp (14), such that an end section of the at least one conductor (68) extends beyond the holding clamp (14).

A quad-shield coaxial cable includes an insulator portion configured to encircle an inner conductor portion, an inner conductive foil portion configured to encircle the insulator portion, an inner braided shield portion configured to encircle the inner conductive foil layer portion, an outer braided shield portion configured to encircle the inner braided shield portion, an outer conductive foil portion configured to encircle the outer braided shield portion, and a jacket portion configured to encircle the outer conductive foil portion.

An electric wire twisting device is provided, which is capable of producing a preferable twisted electric wire from a plurality of electric wires of which both ends are cut. An electric wire twisting device 1 includes a first gripping device 11 including a first clamp 2a that grips a first end of a first electric wire CT, a second clamp 2b that grips a first end of a second electric wire C2, and a first holder 15A that holds the first clamp 2a and the second clamp 2b. The electric wire twisting device 1 includes a second gripping device 12 that grips a second end of the first electric wire CT and a second end of the second electric wire CT, a first revolving actuator 3b that causes the first holder 15A to rotate around a center line of revolution CL, and a first rotating actuator 3a that causes the first clamp 2a and the second clamp 2b to rotate around a center line of rotation that is parallel to the center line of revolution CL or is inclined with respect to the center line of revolution CL.