A connecting apparatus for connecting a current-carrying element to a rail element includes: a receiving body on which the current-conducting element is fastenable, the receiving body having a first transverse side and a second transverse side opposite the first transverse side, and a first longitudinal side and a second longitudinal side opposite the first longitudinal side; a first latching arm for fastening the connecting apparatus to the rail element; and a second latching arm for fastening the connecting apparatus to the rail element. The first latching arm is joined to the first transverse side of the receiving body. The second latching arm is joined to the second transverse side of the receiving body.

A connecting apparatus for connecting a current-carrying element to a rail element includes: a receiving body on which the current-conducting element is fastenable, the receiving body having a first transverse side and a second transverse side opposite the first transverse side, and a first longitudinal side and a second longitudinal side opposite the first longitudinal side; a first latching arm for fastening the connecting apparatus to the rail element; and a second latching arm for fastening the connecting apparatus to the rail element. The first latching arm is joined to the first transverse side of the receiving body. The second latching arm is joined to the second transverse side of the receiving body.

A connection unit includes a plurality of connection elements arranged next to one another. Each connection element has a conductor connection opening for accommodating an electrical conductor and an actuating element for clamping the electrical conductor in the conductor connection opening and/or releasing said conductor. The actuating elements and the conductor connection openings are arranged on a common side of the connection unit. The actuating elements and the conductor connection openings of the connection elements are arranged in two rows which are spaced apart from one another. The connection unit has at least one first connection element of which the actuating element is arranged in a first row and the conductor connection opening is arranged in a second row, and at least one second connection element of which the actuating element is arranged in the second row and of which the conductor connection opening is arranged in the first row.

A wire-clamping connector is provided. The wire-clamping connector includes a housing and a contact element. The housing includes a through hole. The contact element is disposed in the housing, and includes a bottom plate structure and an elastic sheet body. The bottom plate structure is disposed opposite to a top wall of the housing, and includes a protruding portion that has a contact surface. A terminal portion of the elastic sheet body is fixed to the top wall, and the elastic sheet body has an acute-angular structure configured to be adjacent to the contact surface. An insertion interval is defined between the acute-angular structure and the contact surface. A wire core of a wire inserted in the through hole enters the insertion interval and is clamped together by the acute-angular structure and the contact surface, and an elastic restoring force is generated by the pressed elastic sheet body.

The present disclosure discloses a plug connector including an insulating housing, a number of plug terminals and a cable. The insulating housing includes a width direction extending along a left-and-right direction. The plug terminals are retained by the insulating housing and arranged in two rows in the width direction of the insulative housing. The plug terminals of each row are arranged in an upper-and-lower direction and spaced away from each other in the upper-and-lower direction. Each plug terminal extends along a front-and-back direction. The cable includes a number of core wires correspondingly and electrically connected with the plug terminals. A connector assembly including the plug connector and the mated socket connector is also disclosed in the present disclosure.

The present disclosure discloses a socket connector including an insulating base and a number of socket terminals. The insulating base includes an outer plastic frame defining a receiving channel and an inner plastic block received in the receiving channel. The inner plastic block includes two sidewalls opposite to each other in a left-and-right direction. The socket terminals are arranged in two rows by positioning symmetrically and respectively on the two sidewalls of the inner plastic block. The socket terminals of each row are arranged in an upper-and-lower direction and spaced away from each other in the upper-and-lower direction. Each socket terminal extends along a front-and-back direction perpendicular to both the left-and-right direction and the upper-and-lower direction. A connector assembly including the socket connector and the mated plug connector is also disclosed in the present disclosure.

Provided are load bearing universal adaptors for connecting electrical cables in a watertight configuration. The mechanical advantage associated with wedges in a tapered cavity ensures that load is appropriately transferred to the walls of the wedge housing. In this manner, a load applied to the electrical cable is at least partially provided to the walls of the system rather than acting to pull the cable out of the adaptor, and the object to which the adaptor is connected, such as a terminal block.

A poke-in terminal includes a main body, a tab terminal socket at a mating end, and a wire socket at a terminating end. The tab terminal socket includes walls forming a tab terminal receptacle configured to receive a tab terminal. Upper and lower beam contacts extend into the tab terminal receptacle to interface with the tab terminal. The wire socket includes walls forming a wire receptacle configured to receive a wire. Poke-in retention beams extend into the wire receptacle to interface with the wire when poked into the wire socket. The wire socket includes a wire release element configured to be actuated to release the poke-in retention beams from the wire.

A poke-in terminal includes a main body, a tab terminal socket at a mating end, and a wire socket at a terminating end. The tab terminal socket includes walls forming a tab terminal receptacle configured to receive a tab terminal. Upper and lower beam contacts extend into the tab terminal receptacle to interface with the tab terminal. The wire socket includes walls forming a wire receptacle configured to receive a wire. Poke-in retention beams extend into the wire receptacle to interface with the wire when poked into the wire socket. The wire socket includes a wire release element configured to be actuated to release the poke-in retention beams from the wire.

A conductor connection terminal, having an insulating material housing, a busbar, a clamping spring and an operating lever which is pivotably received in the insulating material housing over a pivoting range and can be pivoted between an open position and a closed position, wherein the clamping spring has an operating arm which is deflected via a spring driver of the operating lever at least in the open position, characterized in that the operating lever is supported in the open position at a first and a second support point spaced from the first, and that the operating lever is pulled against the first and the second support point by a tensile force of the clamping spring acting on the spring driver from the operating arm.