An electrical transmission line repair apparatus comprising a first end section, a second end section and a link member. The first and second end sections are spaced apart from each other and each configured to receive and releasably retain a conductor thereacross. The link member is positioned on one side of the first and second end sections, so that the first and second end sections can be coupled to a conductor on either side of a link member, suspension or other device from below, and without decoupling or de-energizing the transmission line. In addition, the installation of the same and the clamping can be achieved from below the conductor upon positioning. That is, the link member or members do not straddle the transmission line, requiring dismantling of the dead end configuration, or the disassembly of the link member from the first and second end section.

A cable foil layer processing equipment includes a rack, a knife holder installed on the rack, a plurality of cutters movably installed on the knife holder and arranged in a crisscross manner in a vertical plane, and a linear moving mechanism configured to move linearly in a horizontal direction parallel to an axial direction of a cable. The rack is installed on the linear moving mechanism so as to move linearly in the horizontal direction along with the linear moving mechanism. The cutters clamp a foil layer of the cable in a radial direction of the cable. The linear moving mechanism drives the knife holder to move in the horizontal direction so as to cut the foil layer of the cable into a plurality of equal parts.

A method of producing a conductive path on a substrate including depositing on the substrate a layer of material having a thickness in the range of 0.1 to 5 microns, including metal particles having a diameter in the range of 10 to 100 nanometers, employing a patterning laser beam to selectably sinter regions of the layer of material, thereby causing the metal particles to together define a conductor at sintered regions and employing an ablating laser beam, below a threshold at which the sintered regions would be ablated, to ablate portions of the layer of material other than at the sintered regions.

A method of producing a conductive path on a substrate including depositing on the substrate a layer of material having a thickness in the range of 0.1 to 5 microns, including metal particles having a diameter in the range of 10 to 100 nanometers, employing a patterning laser beam to selectably sinter regions of the layer of material, thereby causing the metal particles to together define a conductor at sintered regions and employing an ablating laser beam, below a threshold at which the sintered regions would be ablated, to ablate portions of the layer of material other than at the sintered regions.

A cable foil layer processing equipment includes a rack, a knife holder installed on the rack, a plurality of cutters movably installed on the knife holder and arranged in a crisscross manner in a vertical plane, and a linear moving mechanism configured to move linearly in a horizontal direction parallel to an axial direction of a cable. The rack is installed on the linear moving mechanism so as to move linearly in the horizontal direction along with the linear moving mechanism. The cutters clamp a foil layer of the cable in a radial direction of the cable. The linear moving mechanism drives the knife holder to move in the horizontal direction so as to cut the foil layer of the cable into a plurality of equal parts.

A distorted substrate is positioned in a predetermined position and corrected, thereby improving the substrate transfer efficiency. A transport unit capable of transporting and positioning a substrate includes a transport mechanism for transporting the substrate to an unloading position, and a positioning mechanism for positioning the substrate in the unloading position. The positioning mechanism includes a regulating member including at least two pairs of regulating portions capable of abutting against the opposing end faces of the substrate, an abutment moving mechanism for moving one regulating portion toward the other regulating portion in each of the at least two pairs of regulating portions, and a regulation moving mechanism capable of moving the regulating member in a direction in which the substrate is pressed.

A cable preparation machine includes a frame forming a cable cutting zone and having a cable opening along a cable axis at the cable cutting zone receiving an end of a cable. The cable preparation machine includes a pulley assembly rotatably coupled to the frame about the cable axis, a drive assembly operably coupled to the pulley assembly to rotate the pulley assembly about the cable axis, and a blade assembly operably coupled to the pulley assembly and rotated with the pulley assembly about the cable axis. The blade assembly is configured for cutting an insulator from the end of the cable in a first cutting configuration when the cable is positioned in the cable opening and the blade assembly is configured for cutting a cable braid from the end of the cable in a second cutting configuration when the cable is positioned in the cable opening.

A microcircuit deposition system incorporates a first printing engine for depositing a dielectric on a substrate. A microwire spooling machine houses a microwire spool and incorporates a tension guide to position a microwire trace onto the dielectric layer. A second printing engine trails the microwire spooling machine to deposit a covering dielectric layer over the microwire trace.

Provided are an insertion method and an insertion apparatus for efficiently and reliably inserting a plurality of coil elements aligned in a ring shape into respective slots of a stator core. In an insertion method of inserting, the insertion method includes a coil element alignment process S3 of forming an assembly body 50 by assembling the plurality of coil elements 40 in a ring shape in the state where the turn portions 42 alternately overlap each other, a supporting process S42 of supporting the assembly body 50 by using the turn portions 42, and an insertion process S45 of allowing the assembly body 50 and the stator core 60 to be close to each other and inserting the leg portions 41 of the coil elements 40 of the assembly body 50 into the slots 61.

A method for assembling a connectorized electrical equipment comprises a connectivity list required for the connectorized electrical equipment, comprising an origin connector and its identifier; a destination electrical equipment subpart and its identifier thereof; and a list of connections between the origin connector and the destination electrical equipment subpart. By querying a database comprising a library of connectors, a construction plan is generated for the connectorized electrical equipment. The construction plan includes diagrams for assembly, images to assist the assembler, a list of material for managing inventory and instructions. An ATE can be connected to the connectorized electrical equipment to be assembled. Based on the construction plan, instructions are provided for a connection between the origin connector and the destination electrical equipment subpart. Connections can be made manually or using the ATE. All connections are registered in real time for progression tracking and instruction updates.