A clamping arrangement includes: two spring-force terminals, the two spring-force terminals each including a clamping cage and a spring, each of the two clamping cages being able to receive an electrical conductor pushed in an insertion direction and to clamp the conductor between the cage and the spring, a first insertion direction of a first of the two spring-force terminals and a second insertion direction of a second of the two spring-force terminals being arranged at an angle larger than 0 to one another. The two spring-force terminals are arranged one behind the other in one of the insertion directions of the electrical conductor. The first insertion direction of the first of the two spring-force terminals and the second insertion direction of the second of the two spring-force terminals are arranged at a right angle to one another or counter to one another.

A conductor unit includes: a plurality of conductors each including a conducting portion covered with an insulating coating; an annular core that includes a first core constituent portion and a second core constituent portion combined with the first core constituent portion, and that interposes the conductors between the first core constituent portion and the second core constituent portion; and a holding member that makes the first core constituent portion and the second core constituent portion press and hold the conductors therebetween.

A multi-earth terminal includes: a body having a hook piece and a hook rib, which are formed on an outer edge of the body; a barrel coupled with a wire; and a connector interconnecting the body with the barrel. Two or more bodies are stacked vertically and coupled to each other. When the two or more bodies are stacked vertically and coupled to each other, each of the two or more bodies includes the hook rib and the hook piece so that the hook rib of a first body that is located at an upper side of the vertically stacked bodies is inserted into and engaged with the hook piece of a second body that is located at a lower side of the vertically stacked bodies.

A multi-earth terminal includes: a body having a hook piece and a hook rib, which are formed on an outer edge of the body; a barrel coupled with a wire; and a connector interconnecting the body with the barrel. Two or more bodies are stacked vertically and coupled to each other. When the two or more bodies are stacked vertically and coupled to each other, each of the two or more bodies includes the hook rib and the hook piece so that the hook rib of a first body that is located at an upper side of the vertically stacked bodies is inserted into and engaged with the hook piece of a second body that is located at a lower side of the vertically stacked bodies.

This disclosure provides a method and apparatus for connecting and disconnecting a first wire to a second wire. More specifically, an apparatus that includes a first electrical contact, a second electrical contact, an insulated housing, and a male contact prong (i.e., a shunt) is disclosed. In an embodiment, the first and second electrical contacts conductively connect with a first and second wire, respectively, via an insulation displacement connector. Furthermore, the male contact prong conductively connects (i.e., shunts) the first and second electrical contacts together. A wire-to-wire contact with shunt allows for two wires to be quickly and efficiently connected and disconnected.

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

A subsea cable system (10) for transfer of electric power to a subsea device is disclosed where the subsea cable system comprises a subsea cable (11) with a first end portion (26) and a second end portion (27). The first end portion (26) is adapted for connection to a supply of electrical energy. The subsea cable (11) comprises at least a first supply cable (21), a second supply cable (22) and at least one return cable (24, 25) where the first supply cable (21), the second supply cable (22) and the at least one return cable (24, 25) each comprises a conductor element (101, 102, 103, 104) for conduction of an electric current. The subsea cable system (10) further comprises a conductor transition element (66) comprising a conductor element (67) that is provided with at least a first conductor leg (73), a second conductor leg (74) and a third conductor leg (75). The first conductor leg (73) is connected to the conductor element (101) of the first supply cable (21), the second conductor leg (74) is connected to the conductor element (102) of the second supply cable (22) and the third conductor leg (75) is connected to conductor element (56) of an end supply cable (53) that is connectable to a consumer device (46). A method for supplying electrical power to a subsea consumer device of electricity is also disclosed.

A subsea cable system (10) for transfer of electric power to a subsea device is disclosed where the subsea cable system comprises a subsea cable (11) with a first end portion (26) and a second end portion (27). The first end portion (26) is adapted for connection to a supply of electrical energy. The subsea cable (11) comprises at least a first supply cable (21), a second supply cable (22) and at least one return cable (24, 25) where the first supply cable (21), the second supply cable (22) and the at least one return cable (24, 25) each comprises a conductor element (101, 102, 103, 104) for conduction of an electric current. The subsea cable system (10) further comprises a conductor transition element (66) comprising a conductor element (67) that is provided with at least a first conductor leg (73), a second conductor leg (74) and a third conductor leg (75). The first conductor leg (73) is connected to the conductor element (101) of the first supply cable (21), the second conductor leg (74) is connected to the conductor element (102) of the second supply cable (22) and the third conductor leg (75) is connected to conductor element (56) of an end supply cable (53) that is connectable to a consumer device (46). A method for supplying electrical power to a subsea consumer device of electricity is also disclosed.

A fastener for connecting an electrical conductor to a connector body includes a first portion adapted to engage an opening of the connector body and a second portion engaging the first portion. The second portion includes a head, a base coupled to the first portion and including an end adapted to engage the electrical conductor, and a shearable section positioned between the head and the base.

A conductive component for electrically connecting a plurality of terminal portions includes a conductive member including a plurality of connection portions being fastened to the respective terminal portions in a connected state and a case having insulation properties while accommodating the conductive member. The at least one of the connection portions, which is configured to be fastened to the terminal portion covered by a terminal portion cover having a terminal portion opening window, is provided with at least one connection-portion-side relay portion. The connection-portion-side relay portion is arranged to connect to the terminal portion inserted through the terminal portion opening window.