Technology capable of reducing the number of tubular protective members in a wiring member is provided. The wiring member includes: multiple electric wires that branch into multiple branch lines from a main line at a branch position; a connection component provided at an end portion of a target branch line among the branch lines; and a resin molded body that includes a main body portion and an extending portion. The main body portion covers all of the electric wires at the branch position, and the extending portion extends from the main body portion and covers a portion of the target branch line that is between the main body portion and the connection component.

When bending a superconducting cable of a stack conductor structure in which a plurality of layers of tape wires are stacked, a twisting process is performed for the superconducting cable immediately before a bending portion of the superconducting cable.

When bending a superconducting cable of a stack conductor structure in which a plurality of layers of tape wires are stacked, a twisting process is performed for the superconducting cable immediately before a bending portion of the superconducting cable.

The adhesive tape of the present disclosure includes: a substrate; and an adhesive layer disposed on one surface of the substrate. In the adhesive tape of the present disclosure, when a breakdown voltage in a thickness direction of the adhesive tape is represented as X (unit: kV) and an initial elastic modulus evaluated from a stress-strain curve in a tensile test is represented as Y (unit: N/mm), an inequality Y ≤ 4.5X -22.5 is satisfied. The adhesive tape of the present disclosure has an excellent balance between insulating properties and winding properties in winding work.

A high frequency cable connector with a plug connector terminating shielded cables via a plurality of cable connection modules attached to a paddle card. The terminations do not significantly disrupt the high integrity signal paths within the cables, even at high frequencies. Various techniques may be used, alone or in combination, to form the termination, including that the wire insulators and shields of the cables extend almost to the point of termination, with a relatively small length of wire extending beyond the insulator and shield; welding of cable wires to signal terminals in the modules; signal terminals and ground terminals held within the modules with a controlled relative spacing; signal terminals of the modules surface mount soldered to pads on the paddle card; narrow pads approximating the width of traces in the paddle card; and short pads, approximating the length of mounting ends of the signal terminals.

A high frequency cable connector with a plug connector terminating shielded cables via a plurality of cable connection modules attached to a paddle card. The terminations do not significantly disrupt the high integrity signal paths within the cables, even at high frequencies. Various techniques may be used, alone or in combination, to form the termination, including that the wire insulators and shields of the cables extend almost to the point of termination, with a relatively small length of wire extending beyond the insulator and shield; welding of cable wires to signal terminals in the modules; signal terminals and ground terminals held within the modules with a controlled relative spacing; signal terminals of the modules surface mount soldered to pads on the paddle card; narrow pads approximating the width of traces in the paddle card; and short pads, approximating the length of mounting ends of the signal terminals.

A high-voltage DC cable joint including a multi-wall layered construction having individual concentrically arranged layers. The joint includes, from inside to outside, an inner conductive rubber layer, a field grading rubber layer made from a predetermined tailored formulation, an insulating rubber layer and an outer conductive rubber layer. The field grading rubber layer separates and interconnects the conductive rubber layers, and wherein the rubber layers are cross-linked by a by-product-free manufacturing method. The cable joint is preferably made from platinum cured rubbers by moulding process steps. In a preferred embodiment the cable joint is made by injection moulding.

The purpose of the present invention is to make it possible to easily attach an elastic water-stop member to a wiring member. The present invention is a wiring module (10) comprising a wiring member (20), and an elastic water-stop member (30) formed with a through-housing section (32) capable of housing a portion, in the longitudinal direction, of the wiring member, wherein the elastic water-stop member has a slit (36) formed from an outer peripheral portion thereof to the through-housing section, and the slit is kept closed in a state in which the portion in the longitudinal direction of the wiring member is housed in the through-housing section.

Techniques, systems and articles are described for monitoring electrical equipment of a power grid and predicting likelihood failure events of such electrical equipment. In one example, a sensing device is configured to couple to an electrical power cable. The sensing device includes a plurality of concentric layers and a monitoring device. The plurality of concentric layers include a first layer, second layer, and third layer. The first layer is configured to concentrically surround a central conductor of the electrical cable and includes an insulating material. The second layer includes a conducting material. The third layer includes a resistive material configured to resist electrical flow between the second layer and a ground conductor exterior to the third layer. The monitoring device includes a sensor and communication unit configured to output data indicative of the sensor data.

An implosion shield of ballistic fabric adapted to mount so as to surround an implosion sleeve or dead-end on a power line. The implosion shield may be wrapped or formed as an envelope or tent including one piece and folded around the implosion sleeve or dead-end and secured with fasteners. A method of installing the implosion cover may include installing an implosion sleeve or dead-end on a power line, and then installing the implosion shield around the implosion sleeve or dead-end, by wrapping the implosion shield around the implosion sleeve or dead-end, or by securing an envelope implosion shield over the implosion sleeve or dead-end, or by draping the shield over the implosion sleeve or dead-end, or by mounting the shield on a frame over the implosion sleeve or dead-end, then detonating the implosion sleeve or dead-end. The implosion shield attenuates shock, pressure and sound waves from the detonation.