A composite cable comprising at least one data cable and at least one electric power core, with the at least one data cable and at least one electric power core insulated to the same nominal voltage rating.

The invention relates to a high-conductivity composite cable, a cable connector for the cable, as well as to a method for manufacturing the cable. The cable comprises a conductive layer comprising multiple busbars extending parallel to each other in one plane and separated from each other by a dielectric material. Each busbar is made of a homogeneous conductive material. First and second insulation layers are provided on the upper and bottom surface of the conductive layer, respectively. Each insulation layer is made of a polymer self-adhesive tape. A coating layer made of a paper or fabric self-adhesive tape is provided on at least one of the insulation layers. The cable further comprises a reinforcing relief structure on the coating layer(s) and multiple apertures each providing access to one of the busbars through the coating layer(s) and the insulation layer(s). The cable may transmit signals of different forms as accurately and quickly as possible.

Disclosed is a method for forming a square-wire conductor, which includes: providing a circular conductor with a diameter d; passing the conductor through a gap of a longitudinal calendering roller to longitudinally calender the conductor up and down to form a conductor with flat upper and lower surfaces, the gap L1 of the longitudinal calendering roller is 0.886 d to 0.911 d; longitudinally and transversely straightening the conductor; passing the conductor through a gap of a transverse calendering roller to transversely calender the conductor left and right to form a conductor with flat left and right surfaces, the gap L2 of the transverse calendering roller is 0.886 d to 0.911 d; and longitudinally and transversely straightening the conductor.

A cable holding system for positioning a cable relative to a cable processing machine comprises a cable holding device for selectively clamping onto a cable to be processed, and a receiver. The receiver includes an opening for selectively receiving the cable holding device in a predetermined orientation, and a mounting base for fixing the location of the receiver relative to the cable processing machine.

A measurement method for producing an electrical cable wherein an end-side end of a supporting sleeve that is secured to the electrical cable is brought into contact with a reference stop of a reference device. An axial distance between the end-side end of the supporting sleeve and an inner conductor part secured to an inner conductor of the electrical cable and the reference stop is detected, and a connection distance (y) between the front end of the inner conductor part and the end-side end of the supporting sleeve, facing the inner conductor part, is derived from the axial distance.

An electric wire apparatus includes an electric wire including an aluminum alloy wire rod having an outer periphery portion coated, and a crimp terminal crimped to an end portion of the electric wire, the crimp terminal having a barrel portion crimped with the aluminum alloy wire rod, the barrel portion having a one-end closed tubular shape. The aluminum alloy wire rod has a composition including 0.10 mass % to 1.00 mass % of magnesium (Mg), 0.10 mass % to 1.00 mass % of silicon (Si), 0.01 mass % to 2.50 mass % of iron (Fe), 0.000 mass % to 0.100 mass % of titanium (Ti), 0.000 mass % to 0.030 mass % of boron (B), 0.00 mass % to 1.00 mass % of copper (Cu), 0.00 mass % to 0.50 mass % of silver (Ag), 0.00 mass % to 0.50 mass % of gold (Au), 0.00 mass % to 1.00 mass % of manganese (Mn), 0.00 mass % to 1.00 mass % of chromium (Cr), 0.00 mass % to 0.50 mass % of zirconium (Zr), 0.00 mass % to 0.50 mass % of hafnium (Hf), 0.00 mass % to 0.50 mass % of vanadium (V), 0.00 mass % to 0.50 mass % of scandium (Sc), 0.00 mass % to 0.50 mass % of cobalt (Co), 0.00 mass % to 0.50 mass % of nickel (Ni), and the balance including aluminum and inevitable impurities.

A twist application device, including a feeder (1) for feeding conductor ends (2a . . . 2c) of at least two conductors (3a . . . 3c), and a rotatably mounted twist application head (4) for twisting the conductors (3a . . . 3c). The twist application device also includes a controller (7), connected with a drive (8) for first clamping jaws (5a . . . 5f) of the feeder (1), and is equipped for control of the latter. The distance (a) between clamped conductor ends (2a . . . 2c) is set at an adjustable value before the transfer of the conductor ends (2a . . . 2c) from the feed device (1) into the twist application head (4). A method of twisting at least two conductors (3a . . . 3c), in which the referred-to distance (a) is set at an adjustable value before clamping of the conductor ends (2a . . . 2c) in the second jaws (6a, 6b) of the twist application head (4).

A method for manufacturing an insulated conductive material includes providing a continuous feed of a conductive material, a first continuous feed of insulating material above a top surface of the conductive strip, and a second continuous feed of insulating material below a bottom surface of the conductive strip. Portions of the first and second continuous feeds of insulating material are compressed against a portion of the conductive material. The portions of the first and second insulating material are cured to thereby provide a continuous feed of insulated conductive material.

Provided are a micro-nano wire manufacturing device and a micro-nano structure. The micro-nano wire manufacturing device includes a liquid-phase nanomaterial storage device and a micro-nano wire applying mechanism. The liquid-phase nanomaterial storage device is provided with a liquid outlet. The micro-nano wire applying mechanism is provided in one-to-one correspondence with the liquid outlet. The micro-nano wire applying mechanism includes at least two flexible wires. The roots of the flexible wires are secured to the liquid-phase nanomaterial storage device. One ends of the two flexible wires hang down to a substrate and abut against each other. The range of the angle between the projections of the two flexible wires on the substrate is 1 to 5.

An automated apparatus for installing a sleeve on a cable includes a split funnel assembly, a cable feeding mechanism, a robot comprising a robot tool mounting flange and a plurality of robot motors, a sleeve gripper mounted to the robot tool mounting flange, a plurality of heaters, and a computer configured to output commands in accordance with a predetermined computer program. The split funnel assembly includes an actuator and a split funnel comprising a pair of funnel halves which are able to open and close in response to activation of the actuator. Each funnel half comprises a cable guide channel and a funnel extension. While the split funnel is in the funnel closed state, the funnel extensions form a seat for the sleeve and the cable guide channels form a repeatable path for the cable to follow through the funnel. The apparatus further includes a cable centering gripper, a cable clamp assembly, a slug puller assembly, and a ground lead management system.