A pad extender for connecting a conductor cable to a transformer. The pad extender includes a planar body including a first portion and a second portion, the first portion having a first portion length. The pad extender further includes an elongate slot defined in the first portion of the planar body, the elongate slot extending along a majority of the first portion length. The pad extender further includes at least one aperture defined in the second portion of the planar body. Wherein the planar body is slidable relative to the transformer along the elongate slot.

A pad extender for connecting a conductor cable to a transformer. The pad extender includes a planar body including a first portion and a second portion, the first portion having a first portion length. The pad extender further includes an elongate slot defined in the first portion of the planar body, the elongate slot extending along a majority of the first portion length. The pad extender further includes at least one aperture defined in the second portion of the planar body. Wherein the planar body is slidable relative to the transformer along the elongate slot.

The technology relates to an electric current conducting assembly, more specifically with the incorporation of a dead end shoe.

The technology relates to an electric current conducting assembly, more specifically with the incorporation of a dead end shoe.

An induction cable contains a plurality of cable conductors each having a conductor strand surrounded by insulation. The conductor strand contains a plurality of conductor sections which are spaced apart in the longitudinal cable direction at resonance dividing points by insulating intermediate pieces. The induction cable furthermore has a coupling device on which a plurality of the conductor strands are separated forming coupling ends at coupling positions. The coupling ends are connected to each other via the coupling device. A simple providing and installing of the induction cable and a simple replacement of damaged cable parts is thus enabled.

An induction cable contains a plurality of cable conductors each having a conductor strand surrounded by insulation. The conductor strand contains a plurality of conductor sections which are spaced apart in the longitudinal cable direction at resonance dividing points by insulating intermediate pieces. The induction cable furthermore has a coupling device on which a plurality of the conductor strands are separated forming coupling ends at coupling positions. The coupling ends are connected to each other via the coupling device. A simple providing and installing of the induction cable and a simple replacement of damaged cable parts is thus enabled.

A terminal-wire bonding method includes: arranging a first core at a second end of a first terminal-wire having a first terminal connected with the first core exposed from an insulating sheath at a first end, onto a side of an anvil and a second core at a second end of a second terminal-wire having a second terminal connected with the second core exposed, at a first end, from an insulating sheath longer than the insulating sheath of the first terminal-wire, onto a side of a horn; and bonding the first core at the second end and the second core at the second end together by ultrasonic bonding between the horn and the anvil.

A contact-making device (10) is used for a resistance measurement on a test object (30). The test object (30) comprises a threaded hole (31), which has an internal thread (32). The contact-making device (10) is designed to be mechanically coupled to the internal thread (32) of the threaded hole (31). The contact-making device (10) comprises a first contact (11) and a second contact (12), in order to make electrical contact with the test object (30) at, at least, two points when the contact-making device (10) is mechanically coupled to the internal thread (32). The first contact (11) and the second contact (12) are electrically insulated from one another by an insulating material (15-17) in the contact-making device (10).

A contact-making device (10) is used for a resistance measurement on a test object (30). The test object (30) comprises a threaded hole (31), which has an internal thread (32). The contact-making device (10) is designed to be mechanically coupled to the internal thread (32) of the threaded hole (31). The contact-making device (10) comprises a first contact (11) and a second contact (12), in order to make electrical contact with the test object (30) at, at least, two points when the contact-making device (10) is mechanically coupled to the internal thread (32). The first contact (11) and the second contact (12) are electrically insulated from one another by an insulating material (15-17) in the contact-making device (10).

An electrical connector includes a compression device defining an aperture and is configured to receive a first portion of a base row of wires and a first portion of a core of an electrical conductor within the aperture. An outer tube defines a central through hole and is configured to receive the compression device within the central through hole. A first end of the outer tube is configured to be compressed around the first end of the compression device, and a first portion of the core of the associated electrical conductor to create a compressed assembly. The compressed assembly is contiguous with a second portion of the base row of wires and a second portion of the core of the associated electrical conductor.