A single element electrical connector includes a single conductive contact element formed into a cage structure having a wire insert end and a wire contact end along a longitudinal centerline axis of the connector. The cage structure defines an upper pick-up surface having a surface area suitable for placement of a suction nozzle of a vacuum transfer device, as well as a pair of contact tines biased towards the centerline axis to define a contact pinch point for an exposed core of a wire inserted into the connector. A contact surface is defined by a member of the cage structure for electrical mating contact with a respective contact element on a component on which the connector is mounted.

An electrical connection terminal includes: a connection terminal housing having a conductor insertion opening; a busbar arranged in the connection terminal housing; a spring element rotatably mounted in the connection terminal housing and pivotable into an open position and into a closed position, a conductor inserted into the conductor insertion opening being clampable against the busbar by the spring element in the closed position; and an actuation element rotatably mounted in the connection terminal housing and by which the spring element can be actuated for transfer into the open position and into the closed position. The actuation element includes a base body, which has a tool insertion opening, and an actuation arm. The base body and the actuation arm are formed in two parts, the actuation arm being formed pivotally movable relative to the base body.

A connection device for a shield conductor of an electrical line includes: a housing attachable to a potential collector, into which housing the electrical line with the shield conductor is insertable; a spring element which is arranged adjustably on the housing, which spring element has a clamping leg and is movable relative to the housing from an open position into a clamping position in order to, in the clamping position, act with the clamping leg on the shield conductor of the electrical line inserted in the housing; and a locking element which is adjustable, relative to the housing, between a locking position, in which the housing attached to the potential collector is locked with the potential collector, and an unlocking position for releasing the housing from the potential collector.

The present invention relates to a terminal (1) with a spring force terminal connection (2) with at least one conductor terminal point (K), an insulating material housing (6), a conductor introduction channel (60), and a release lever (5). The release lever (5) is mounted in the insulating material housing (6) pivotably about a pivot axis (A) extending transverse to a conductor introduction direction (E) of an electric conductor between an idle position with closed conductor terminal point (K) and an actuating position with opened conductor terminal point (K). The release lever (5) has two lever arm portions (50) which are spaced apart from one another and which are immersed on both sides of the conductor introduction channel (60) at least partially into the insulating material housing (6). The lever arm portions (50) have in each case a guide portion (53) which face one another and form between them at least a part of the conductor introduction channel (60). The guide portions (53) in the idle position and/or in the actuating position, as seen in the conductor introduction direction, run toward the conductor terminal point (K) in a manner which narrows the conductor introduction channel (60).

Terminal (1), in particular screw or connecting terminal, having a spring force terminal connection (2) with at least one conductor terminal point (K) for electrical connection of at least one conductor, an insulating material housing (6) which at least partially accommodates the spring force terminal connection (2), for each conductor terminal point (K) a conductor introduction channel (60) which extends in a conductor introduction direction (E) from the outside toward the conductor terminal point (K), and for each conductor terminal point (K) a release lever (5) which is mounted in the insulating material housing (6) pivotably about a pivot axis (A) extending transverse to the conductor introduction direction (E), in order to interact with an actuating portion (52) by pivoting of the release lever (5) with the spring force terminal connection (2) for optional opening of the conductor terminal point (K). The release lever (5) has two lever arm portions (50) which are spaced apart from one another and which are immersed on both sides of the conductor introduction channel (60) at least partially into the insulating material housing (6). The lever arm portions (50) have in each case a guide portion (53) which at least partially delimit the conductor introduction channel (60) on both sides at least in the case of a conductor terminal point (K) opened by the release lever (5). According to a first aspect, the release lever (5) has a connection portion (56) which extends along the pivot axis (A) between the lever arm portions (50) and connects these to one another. According to an alternative or additional second aspect, the insulating material housing (6) has guide wall portions (63) which, together with the guide portions (53), at least partially delimit the conductor introduction channel (60), wherein the guide portions (53) are separated from the guide wall portions (63) by a gap (S).

A power connector includes a terminal block holding terminals in terminal channels with terminating ends configured to be electrically coupled to corresponding wires at separable interfaces. The power connector includes a rear insert covering the terminating ends of the terminals having wire ports configured to receive the corresponding wires during a wire poke-in process. The power connector includes biasing members associated with the terminals each including a pusher configured to be biased against the wire to push the wire into direct physical contact with the separable interface of the corresponding terminal. The power connector includes a release mechanism includes a plurality of pusher release elements. The release mechanism is actuated to release the pushers of each of the biasing members from the corresponding wires.

A lever connector for contacting electrical conductors includes features and improvements over other lever connectors. The lever connector includes a housing, a busbar located within the housing, one or more lever mechanisms, and one or more resilient members that connect the lever mechanisms to the busbar. The lever mechanism includes a lever located on a near side of the busbar bridge and a lifting mechanism located on a far side of the busbar bridge opposite the near side of the busbar bridge. When the lever is actuated and lifted upwards and away from the housing, the lifting mechanism moves the resilient member to release away from the busbar. When the lever is closed and pushed downward toward the housing, the lifting mechanism moves the resilient member downward to push the electrical conductor against the busbar, thereby making electrical contact between the electrical conductor and the busbar.

A connection arrangement for connecting an electrical conductor includes: a housing; a busbar; a clamping spring including a clamping leg transferrable into a clamping position and into a release position; a conductor connection space formed between a section of the busbar and the clamping leg of the clamping spring; a displaceably arranged guide element, which is in operative connection with the clamping leg of the clamping spring, the clamping leg being holdable in the release position by the guide element; a release element, which, in the release position of the clamping leg of the clamping spring, is in engagement with the guide element, the release element during insertion of the conductor to be connected into the conductor connection space being actuatable thereby such that the release element comes out of engagement with the guide element and the guide element is displaceable by a spring force of the clamping leg.

A spring-loaded terminal is designed as a direct plug-in terminal for connecting a conductor. The terminal includes a busbar for contacting the conductor, a clamping spring for retaining the electrical conductor in the terminal, and a retaining spring for latching the clamping spring in an open position so that the conductor can be inserted into a contact area. The clamping spring has a pivotable clamping leg and a clamping edge. The retaining spring has a pivotable pivoting leg having at least one retaining device as a first latching device. The clamping leg has a corresponding latching device cooperating with the retaining device of the pivoting leg in a latching state of the clamping leg. The clamping leg is adjustable from the latching state by displacing the electrical conductor into a clamping state in which the clamping leg is unlatched from the retaining device and presses the electrical conductor with the clamping edge of the clamping leg against the busbar. The latching device of the clamping leg is spaced from the clamping edge of the clamping leg.

A connection arrangement for connecting an electrical conductor includes: a busbar; a clamping spring including a clamping leg which tranferrable into a clamping position and into a release position; a conductor connection space formed between a section of the busbar and the clamping leg of the clamping spring; a displaceably-arranged guide element, which is in operative connection with the clamping leg of the clamping spring, the clamping leg being holdable in the release position by the guide element; and a release element which, in the release position of the clamping leg of the clamping spring, is in engagement with the guide element. The release element, during insertion of the electrical conductor to be connected into the conductor connection space, is actuatable by the insertion such that the release element comes out of engagement with the guide element. The guide element is displaceable by a spring force of the clamping leg.