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.

The present disclosure relates to the technical field of electrical connection, in particular to a self-coupled wire connector using a bend spring sheet and conductor sheet, including a main body, a spring sheet and a conductor sheet; a coupling space for accommodating the spring sheet and the conductor sheet is formed inside the main body; a wire plugging hole passing through the coupling space is formed in the main body; the spring sheet and the conductor sheet are assembled in the coupling space, and are kept in a self-coupling state through the coupling space; a wire presses against the spring sheet and the conductor sheet to force the spring sheet and the conductor sheet to be self-coupled.

The present disclosure relates to the technical field of electrical connection, in particular to a self-coupled wire connector using a bend spring sheet and conductor sheet, including a main body, a spring sheet and a conductor sheet; a coupling space for accommodating the spring sheet and the conductor sheet is formed inside the main body; a wire plugging hole passing through the coupling space is formed in the main body; the spring sheet and the conductor sheet are assembled in the coupling space, and are kept in a self-coupling state through the coupling space; a wire presses against the spring sheet and the conductor sheet to force the spring sheet and the conductor sheet to be self-coupled.

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 system that may include a bus bar that may include a mounting bracket configured to electrically couple the bus bar to a motor. The mounting bracket may also be configured to be removably coupled to the motor with at least one fastener. A transducer may be electrically coupled to the bus bar and have transducer elements. A dielectric material may be disposed between the bus bar and the transducer to prevent debris from contacting the active transducer elements and electrical arcing from occurring.

An electrical connector comprise an insulating housing, a spring clip disposed in the insulating housing, and control pieces for opening the spring clip. The insulating housing comprises outer wall sections separately corresponding to wire inserting spaces defined inside the insulating housing. Each outer wall section at least partially extends into a gap formed by a corresponding control piece when the control pieces are switched to a closed state. Moving spaces are defined on an outside of two sides of each of the outer wall sections. The control pieces perform an opening operation and a closing operation in the moving spaces. When the control pieces are in an open state, the spring clip is observed along the moving spaces. Along a width direction of the spring clip, the spring clip is at least partially exposed in projections of the moving spaces along an up-down direction of the moving spaces.

An electrical connector comprise an insulating housing, a spring clip disposed in the insulating housing, and control pieces for opening the spring clip. The insulating housing comprises outer wall sections separately corresponding to wire inserting spaces defined inside the insulating housing. Each outer wall section at least partially extends into a gap formed by a corresponding control piece when the control pieces are switched to a closed state. Moving spaces are defined on an outside of two sides of each of the outer wall sections. The control pieces perform an opening operation and a closing operation in the moving spaces. When the control pieces are in an open state, the spring clip is observed along the moving spaces. Along a width direction of the spring clip, the spring clip is at least partially exposed in projections of the moving spaces along an up-down direction of the moving spaces.

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 bus bar assembly includes a nonconductive terminal cap configured to at least partially surround an electrically conductive terminal. The terminal cap has a perimeter wall configured to circumscribe at least a portion of the terminal to provide a gap configured to expose the terminal. The terminal cap includes a first attachment feature. The bus bar assembly also includes a bus bar having an end configured to mechanically and electrically engage the terminal in an assembled condition and a nonconductive shroud enclosing the bus bar. The shroud includes a second attachment feature configured to removably engage the first attachment feature in the assembled condition to secure the shroud to the terminal cap. A method of electrically connecting cells of a battery is also provided.

A bus bar assembly includes a nonconductive terminal cap configured to at least partially surround an electrically conductive terminal. The terminal cap has a perimeter wall configured to circumscribe at least a portion of the terminal to provide a gap configured to expose the terminal. The terminal cap includes a first attachment feature. The bus bar assembly also includes a bus bar having an end configured to mechanically and electrically engage the terminal in an assembled condition and a nonconductive shroud enclosing the bus bar. The shroud includes a second attachment feature configured to removably engage the first attachment feature in the assembled condition to secure the shroud to the terminal cap. A method of electrically connecting cells of a battery is also provided.