A bonding wire conductively connected to a pipe having a pipe body and a conductive tab mounted to the pipe and having a hole therein, the bonding wire being in the form of a braided conductive cable provided with a connector at each of its ends, the bonding wire being tightly wound around the pipe body and the ends both passing through the hole in the connector such that the ends of the bonding wire extend away from the pipe body after passing through the hole, while a portion of the bonding wire between the end portions is wrapped tightly around the pipe body; the bonding wire held under tension around the pipe body by a crimp around the two end portions where they pass through the hole.

A bonding wire conductively connected to a pipe having a pipe body and a conductive tab mounted to the pipe and having a hole therein, the bonding wire being in the form of a braided conductive cable provided with a connector at each of its ends, the bonding wire being tightly wound around the pipe body and the ends both passing through the hole in the connector such that the ends of the bonding wire extend away from the pipe body after passing through the hole, while a portion of the bonding wire between the end portions is wrapped tightly around the pipe body; the bonding wire held under tension around the pipe body by a crimp around the two end portions where they pass through the hole.

The invention relates to a method of connecting electrical wires, conductors, or connections together by rotating the connector ends in an enclosure to tightly twist the wire ends together and also includes a clamping mechanism to prevent the wires from untwisting, becoming loose, or falling out of the enclosure. The present invention increases the holding ability of current rotating tools for electrical wires and connections.

The invention relates to a method of connecting electrical wires, conductors, or connections together by rotating the connector ends in an enclosure to tightly twist the wire ends together and also includes a clamping mechanism to prevent the wires from untwisting, becoming loose, or falling out of the enclosure. The present invention increases the holding ability of current rotating tools for electrical wires and connections.

The invention relates to a method of connecting electrical wires, conductors, or connections together by rotating the connector ends in an enclosure to tightly twist the wire ends together and also includes a clamping mechanism to prevent the wires from untwisting, becoming loose, or falling out of the enclosure. The present invention increases the holding ability of current rotating tools for electrical wires and connections.

A wire preparation device includes a motor, a device housing coupled to the motor, and a wire spinner held by the device housing. The wire spinner is mechanically connected to the motor via power coupling components. The wire spinner extends to a wire end that protrudes from the device housing. The wire spinner includes a collet sleeve defining a channel configured to receive an end of one or more wires of a cable therein through an opening at the wire end. The wire spinner further includes an outer collar surrounding the collet sleeve and selectively movable relative to the collet sleeve to force the collet sleeve to contract radially inward for releasably securing the one or more wires within the channel. The wire spinner is rotated by the motor relative to the device housing to untwist or straighten the one or more wires secured within the collet sleeve.

The present application discloses a softening device (200) by which an outer insulating layer of an elongate electrical heating element (121) to be secured onto a cushion, especially a vehicle seat or rest cushion is able to be softened, the softening device (200) comprising: a body (210), wherein the body is provided with a gas passage, a feeding passage (211), and an open cavity (213), wherein hot air is able to be driven through the gas passage, and the elongate electrical heating element (121) is able to be conveyed through the feeding passage (211), wherein the gas passage and the feeding passage (211) are isolated from each other but both of them open into the open cavity (213), wherein after passing through the feeding passage (211) and the open cavity (213), the electrical heating element (121) is able to be discharged out of the body (210). The present application also discloses an electrical heating element (121), a sewing apparatus comprising the softening device, and a method for controlling the softening device.

A tool for wrapping a formed wire around a cable is provided. The tool includes a handle portion and a head portion. The handle portion has an elongated body and a hand grip portion attached to the elongated body. The head portion has a cover pivotably attached to a base. When the cover is pivoted into contact with the base a cable receiving opening is formed between the cover and the base. The head portion also includes a pusher member extending from the cover or the base into the cable receiving opening. The pusher member is adapted to contact and push strands of a formed wire when the tool is in use.

A system includes a pair of terminal leads joined together. An insulative sleeve is wrapped around the pair of terminal leads. Lacing binds around the insulative sleeve. Cured epoxy can encase the insulative sleeve and lacing. The insulative sleeve can include fiberglass. The insulative sleeve can be wrapped more than 360 around the pair of terminal leads so that a first edge of the insulative sleeve is tucked under a second edge of the insulative sleeve.

A system includes a pair of terminal leads joined together. An insulative sleeve is wrapped around the pair of terminal leads. Lacing binds around the insulative sleeve. Cured epoxy can encase the insulative sleeve and lacing. The insulative sleeve can include fiberglass. The insulative sleeve can be wrapped more than 360 around the pair of terminal leads so that a first edge of the insulative sleeve is tucked under a second edge of the insulative sleeve.