A coating removal tool includes a base part and a cover part, to remove a coating of an optical fiber by overlapping the cover part and the base part. The base part and the cover part are made of resin, and include at least a pair of coating removal blades including a base front blade portion provided on the base part and a cover front blade portion provided on the cover part. The base part includes a V-groove which sandwiches the optical fiber in either one or both of a front and rear of the optical fiber in the longitudinal direction and the cover part includes a V-groove which sandwiches the optical fiber and is provided on a side where the V-groove exists in the front and rear of the longitudinal direction in a state where the cover part and the base part are overlapped.

A shield trim is performed by tearing bunched shield strands circumferentially along a circular edge. The apparatus includes a pair of aligned metal plates that have been drilled through multiple times such that holes of varying diameters pass may be passed through both plates. A cable gripper on the entry side of the device clamps the cable in place. A shield gripper on the rear side of the device closes over the exposed shielding of the cable, and the two plates are pushed together. The shield gripper travels with the rear plate, pushing the shield over the wires and causing the shield to bunch between the two plates. With the two plates pushed together, both grippers open and the cable is pulled free from the device. This pull forces a stress concentration on the shield strands as they are pulled and subsequently torn across the sharp edge of the hole, producing a uniformly trimmed shield.

A power supply device is provided, which includes a plurality of battery packs and a plurality of unidirectional conductive elements. The plurality of battery packs are connected in parallel with each other and disposed toward the same direction. The unidirectional conductive elements are connected in serial to the battery packs, respectively. A positive pin of each of the unidirectional conductive elements is connected in serial to a positive terminal of the corresponding battery pack, and a negative pin of each of the unidirectional conductive elements is connected in parallel to negative pins of other unidirectional conductive elements. Therefore, the present disclosure is capable of preventing the battery packs having relatively lower voltages from being charged by the battery packs having relatively higher voltages, thereby prolonging lifetimes of batteries, and avoid from affecting power to be supplied to a power receiving circuit from the battery packs.

A light string, an automatic assembly apparatus and an automatic assembly method thereof are provided. The method includes steps of: arranging lamp housings in a lamp housing carrier by using an assembly machine; actuating a holder to move horizontally by using the assembly machine to align light-emitting elements with accommodating spaces of the lamp housings, respectively; actuating the holder to move vertically toward the lamp housing carrier by using the assembly machine to move the light-emitting elements into the accommodating spaces to be bonded to the lamp housings, respectively; removing a first wire and a second wire together with the light-emitting elements from the holder by the assembly machine; passing the first wire and the second wire through lamp housing through holes of the lamp housings by using the assembly machine; and taking out the light string from the lamp housing carrier by using the assembly machine.

A cable processing apparatus including a frame; a cable guide coupled to the frame; a first cable clamp adjacent the cable guide; a second cable clamp adjacent the cable guide where the first cable clamp is disposed between the cable guide and the second cable clamp; and a controller configured to move the second cable clamp to a clamped position such that a cable extending through the cable guide is clamped by the second cable clamp, move the second cable clamp, relative to the cable guide, in a direction extending along the cable such that a first portion of the insulation is removed from the cable at the first score to expose shielding of the cable, and move the second cable clamp, relative to the first cable clamp, in the direction extending along the cable to cut the shielding to expose one or more conductor of the cable.

A method of reducing entanglement of wires includes receiving, at a tray, one or more first wires of a first wire group from a wire feed system of a wire processing machine. In addition, the method includes receiving, at the tray, one or more second wires of a second wire group from the wire feed system after receiving the first wire group at the tray. The method further includes physically separating, using a separator device associated with the tray, at least a portion of the first wire group from the second wire group. The method also includes moving the second wire group relative to the first wire group, reducing movement of at least a portion of the first wire group relative to a tray surface during movement of the second wire group relative to the first wire group.

A device for processingparticularly stripping insulation, cutting, contacting, fitting-out, connecting, measuring or checkinga cable that has at least one insulated electrical conductor includes a metal tool movable relative to the cable and a measuring device by which contact with the electrical conductor by the tool is detectable. The tool is connected with a first electrode body movable relative to a second electrode body so that through the two electrode bodies, which bodies are separated from one another by an air gap or an insulating material, a coupling capacitor is formed, by which the metal tool is or can be coupled to the measuring device, to an alternating voltage source or to an electrical potential.

A foil peeling apparatus includes an electric wire gripping unit configured to grip a multi-core electric wire including wire members linearly arranged in parallel, a foil covering the wire members, and a sheath covering the foil, the sheath being peeled off at a tip end portion of the electric wire such that the foil is exposed. The foil peeling apparatus further includes: a wire member space forming unit configured to be pressed against an exposed portion of the foil between the wire members so as to form a space between the wire members; a foil cutting unit configured to be abutted against the exposed portion of the foil corresponding to the space formed between the wire members so as to form a cut in the foil; and a foil removal unit configured to open the foil from the cut, and cut the foil which has been opened.

A cable stripping tool is secured between a pair of planks in turn secured within a miter box. Each plank has a plurality of apertures which correspond to gauges of cable stripping sections disposed within the cable stripping tool.

A wire processing system includes a tray having at least one tray surface configured to sequentially receive a first wire and a second wire from a wire feed system of a wire processing machine. The tray surface has a surface feature configured to provide a wire-to-surface coefficient of friction between the tray surface and the first wire higher than a wire-to-wire coefficient of friction between the first wire and the second wire laying on top of the first wire. The wire-to-surface coefficient of friction reduces movement of at least a portion of the first wire relative to the tray surface during movement of the second wire relative to the first wire.