The disclosure relates to a cable sequence for wiring of an electrical circuit with a series arrangement of a plurality of pre-assembled cables, each of which has a first cable end and a second cable end which lies opposite the first cable end, wherein each of the pre-assembled cables has a conductor and a conductor insulation, and wherein the cable ends are processed for the wiring of an electrical circuit in such a manner that a respective conductor end is insulation-free at the first cable end and at the second cable end, and connections between adjacently arranged pre-assembled cables in the series arrangement, wherein, by means of the connections, in each case a first cable end of a pre-assembled cable, produced beforehand as free cable end, and a second cable end of a next pre-assembled cable in the series arrangement, produced beforehand as free cable end, are connected to one another. Furthermore, a method for producing a cable sequence for wiring an electrical circuit and the use of a cable sequence are provided.

A signal lead adapter according to the present invention comprises at least a clamper which is formed at one end of a base plate and two clamping plates integrally formed with and upwardly extending from the base plate. Each clamping plate comprises a first clamping section with a predetermined length and a first clamping surface forming into a first holding ditch with a first radius. Each clamping plate also comprises a second clamping section with a predetermined length and a second clamping surface forming a second holding ditch with a second radius. The signal lead of different radius can be inserted and hold in either the first holding ditch or the second holding ditch. The signal lead can be inserted into the adapter and pulled out from the same easily without causing damage of the flexibility as well as the metal coating layer of the clamping plates.

A plug-on neutral (PON) device includes a housing that defines a phase cooperation portion configured to physically cooperate with phase buses of a bus assembly. The phase cooperation portion is configured to be electrically isolated from the phase buses and stabilize the PON device when installed on the bus assembly. A neutral cooperation portion is configured to physically cooperate with the neutral bus and to physically stabilize the PON device when installed. An electrical connector disposed at the neutral cooperation portion is configured to electrically connect to the neutral bus at an external end and to electrically connect to a conductive current path at its internal end. A lug assembly has one or more conductive terminal lugs, each terminal lug configured to receive current from an external neutral source via an aperture in the lug end of the housing and to electrically connect to the current path.

A connector includes an insulating housing, a conductor unit having a plurality of conductors arranged in a row and an insulating holding body integrally molded with the conductors, and a sealing member that seals between the conductor unit and the housing. Each of the conductors includes a plate-shaped body and terminal parts provided at both ends of the body, respectively. The holding body includes a fitting part fitted to the housing, a plurality of covering parts each extending from the fitting part along the body and individually surrounding the body, and insulating walls each dividing two adjacent terminal parts. Each of the insulating walls has a main wall part and the main wall part extends on an extension line of a gap between two adjacent covering parts and divides two adjacent terminal parts.

A tap connector that includes a tap body and an insulation piercing assembly or module is provided. The insulation piercing assembly is secured to the tap body and movable relative to the tap body. The insulation piercing assembly includes a conductive body, at least two sets of electrically conductive insulation piercing teeth secured to the conductive body and a non-conductive cap or coating covering the teeth. When the teeth pierce the non-conductive caps or coating exposing the teeth, the teeth can pierce insulation surrounding the main and tap conductors creating an electrically conductive path between the main conductor and the tap conductor.

A tap connector that includes a tap body and an insulation piercing assembly or module is provided. The insulation piercing assembly is secured to the tap body and movable relative to the tap body. The insulation piercing assembly includes a conductive body, at least two sets of electrically conductive insulation piercing teeth secured to the conductive body and a non-conductive cap or coating covering the teeth. When the teeth pierce the non-conductive caps or coating exposing the teeth, the teeth can pierce insulation surrounding the main and tap conductors creating an electrically conductive path between the main conductor and the tap conductor.

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 pad extender further includes a pair of through-openings defined in the first portion of the planar body. Each of the pair of through-openings is configured to receive two fasteners. The pad extender further includes at least one aperture defined in the second portion of the planar body. The planar body is slidable relative to the transformer along the pair of through-openings.

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 pad extender further includes a pair of through-openings defined in the first portion of the planar body. Each of the pair of through-openings is configured to receive two fasteners. The pad extender further includes at least one aperture defined in the second portion of the planar body. The planar body is slidable relative to the transformer along the pair of through-openings.

A cable assembly (100) having a first cable (20) having a first conductor (22), a second cable (40) having a second conductor (42) and an electrically conducting joining element (60). The joining element (60) has a first opening (61) and a second opening (63). The cable assembly (100) comprises a number of canted coil springs (70). A terminal portion of the first conductor (22) is secured to the first opening (61) by means of a first canted coil spring (70). A terminal portion of the second conductor (42) is secured to the second opening (63) by means of a second canted coiled spring (70).

A cable assembly (100) having a first cable (20) having a first conductor (22), a second cable (40) having a second conductor (42) and an electrically conducting joining element (60). The joining element (60) has a first opening (61) and a second opening (63). The cable assembly (100) comprises a number of canted coil springs (70). A terminal portion of the first conductor (22) is secured to the first opening (61) by means of a first canted coil spring (70). A terminal portion of the second conductor (42) is secured to the second opening (63) by means of a second canted coiled spring (70).