A conductor terminal for clamping an electrical conductor having an insulating material housing and a contact element. The contact element includes a sheet metal part with at least one clamping spring arranged therein. The insulating material housing has at least one insertion guide channel leading towards a respective clamping spring. An opening is provided in the sheet metal part for receiving an electric conductor introduced into an associated insertion guide channel. The insulating material housing has a channel side wall that defines the insertion guide channel and extends into the opening.

A wire connection terminal device includes a main body and a pressing/moving unit assembled with the main body. The pressing/moving unit has a shafted section, a cam section connected with the shafted section and a force application section formed on the cam section and a press section formed on the cam section. The cam section can freely rotate or swing within a chamber defined by the main body. A metal leaf spring is disposed in the chamber of the main body for pressing and electrically connecting with a conductive wire. The metal leaf spring is responsive to the motion of the pressing/moving unit to release the conductive wire. The wire connection terminal device improves the shortcomings of the conventional structure that the volume of the case and the operational space are larger and the motional travel is longer.

An electrical contact for use in connecting electrical wires is disclosed. The electrical contact includes a cage-like structure, a wire connecting portion, and a flexing contact portion. The cage-like structure includes a plurality of sidewalls and is configured to receive a wire. The wire connecting contact portion includes at least two contact tines that are configured to conductively couple with a corresponding wire. The flexing contact portion includes an end wall, an elastic portion, an extension portion, and a nose portion. The flexing contact portion can store elastic energy and apply a force to a corresponding electrical component.

A connection device comprises at least one direct-plug-in clamping connection which has a direct-plug-in design for plugging in an electric conductor and which has a clamping spring, busbar and/or a clamping cage. The clamping spring is designed to clamp an electric conductor plugged into the direct-plug-in clamping connection to contact the busbar and/or the clamping cage in an electrically conductive manner. The direct-plug-in clamping connection additionally has an actuation mechanism which can be moved from a base position to an actuation position and back. In the actuation position, the actuation mechanism moves the clamping spring so as to release the electric conductor, wherein the actuation mechanism has at least two actuation regions which are provided for an actuation tool and which are arranged at an angle greater than 0 ? relative to each other. When the actuation mechanism is moved from the base position to the actuation position and returned back to the base position from the actuation position, it is moved about an imaginary rotational point which changes the position. A series connection assembly comprises at least two such connection devices designed in the form of series connection devices. A method is provided for installing such a connection device.

A plug system includes a plug connector part, which has a plug connector housing and a multiplicity of connection terminals, which are arranged on the plug connector housing and which each have a spring element forming a clamping leg, and a plug device, which has a multiplicity of electrically conductive plug elements. The plug elements of the plug device for electrically contacting the connection terminals of the plug connector part can each be connected in a plugging manner along a plugging direction to one of the connection terminals of the plug connector part and, in a connected position, are mechanically operatively connected to the clamping leg of the spring element of the respective connection terminal. At least some of the plug elements have a different height measured along the plugging direction.

A contact spring assembly for the self-locking contacting of a wire (28) of an electrical conductor includes a support wall (24) made of a conductive material and a contact spring (10). The contact spring (10) has a base leg (20) held stationary with respect to the support wall and a clamping leg (18) which, together with the support wall (24), forms an insertion receptacle (26) for the wire (28) of the conductor. The insertion receptacle is tapered in the insertion direction. The base leg (20) of the contact spring transitions into a holding leg (22 22), which is inserted into a receiving shaft (30) stationary with respect to the support wall (24) and has two detent projections (38), which protrude perpendicularly to the base leg in opposite directions and are locked to mating contours (34) on the walls of the receiving shaft.

The invention relates to an electrical contact piece having an integrated stop, an L-shaped main contact body having a long and a short arm, the long arm having fastening means for fixing the contact piece in a housing and a bent-out stop piece, and the short arm having an electrical contact surface, and at least one clamping device attached to the long arm of the main contact body for clamping an electrical conductor introduced into the contact piece between a clamping part and the long arm.

Electrical wiring devices that incorporate clamp-type wire terminal connections are described. The electrical wiring devices include for example, single and duplex blade-type electrical receptacles, blade-type locking electrical receptacles, single or multi-pole electrical switches, combination switches and blade-type receptacles, blade-type plugs for electrical cords and blade-type connectors for electrical cords. The electrical wiring devices include a plurality of contact assemblies. Each contact assembly includes a wire terminal and a plunger.

An electrical conductor connection element has a contact carrier, at least one first contact element and at least one second contact element. An electrical conductor can be connected to and contacted with the conductor connection element on the first contact element. The second contact element is connected to the first contact element and guided on the outside of the contact carrier. The conductor connection element furthermore has a separation point which serves to separate the electrical connection of the first contact element to the second contact element.

An electrical contact limiter structure of wire connection terminal has a simplified structure and is easy to operate to enhance the stability of the operation and motion of a metal leaf spring. The wire connection terminal includes conductive components mounted in the insulation case and electrical contact assembled with the conductive components. The electrical contact has a limiter for receiving the metal leaf spring and restricting moving path thereof. The limiter is partitioned into at least one space. A limitation mechanism is assembled with the limiter. The metal leaf spring is mounted in the space. The wiring circuits or conductive wires coming from an apparatus can be easily directly plugged into the space of the limiter to insert with the metal leaf spring. The limiter and the limitation mechanism cooperatively prevent the metal leaf spring from being deflected and over-bent and damaged in operation.