A power input terminal block includes terminals received in terminal channels of a housing each having a main body defining a wire pocket receiving a supply wire and a take-off tab electrically connected to the main body. The power input terminal block includes clamp contacts coupled to the take-off tabs each having a base, a spring beam extending from the base, and a cap extending from the spring beam having a poke-in window configured to receive a take-off wire. An edge defining the poke-in window engages the take-off wire and pulls the take-off wire against the wire side of the take-off tab. The power input terminal block includes release levers coupled to the housing to move the spring beam to an extended position to allow loading and removal of the take-off wire from the clamp contact and the take-off tab.

In an electric work vehicle, a power feeding assembly which connects a battery device to a power controller unit so as to feed power includes a fixed connector which is fixed to the battery device and electrically connected to the battery device, a cable harness connected to a power controller unit, and a free connector which is connected to an end of the cable harness and connectable to a fixed connector, and a connecting operation tool is configured to be movable the free connector between the connecting position in which the free connector is connected to the fixed connector and the detaching position.

A connector is provided with a housing having a facing surface (41) facing a mating connector when the connector is assembled with the mating connector, a terminal held in the housing and projecting in a first direction (D1) from the facing surface, and a cover (56) to be held on the housing. The housing includes a peripheral wall (36) projecting in the first direction from the facing surface and provided to surround the terminal when viewed from a second direction opposite to the first direction. The peripheral wall (36) is provided with an exposure opening (51) for exposing inside of the housing. The cover is provided to be displaced between a first position where the cover closes the exposure opening and a second position (P2) where the cover is retracted from the exposure opening.

A connector according to one aspect of the present disclosure is provided with a housing having a facing surface facing a mating connector when the connector is assembled with the mating connector, a terminal held in the housing and projecting in a first direction from the facing surface, and a cover to be held on the housing. The housing includes a peripheral wall projecting in the first direction from the facing surface and provided to surround the terminal when viewed from a second direction opposite to the first direction and a connection opening formed by the peripheral wall surrounding the terminal when viewed from the second direction. The peripheral wall is provided with an exposure opening communicating with the connection opening and configured to expose inside of the housing.

The present invention relates to an electrical plug connector for an electrical connection system. The electrical plug connector comprises a plug connector housing comprising a housing body and a busbar portion. The busbar portion is at least partially accommodated in the plug connector housing. The busbar portion includes a busbar conductor, and a busbar end which is integrally formed with the busbar conductor. The busbar end includes a connection portion that is configured for being plugged to a mating connector to establish an electrical connection. The busbar end further includes a retention means which is configured to engage with a corresponding retention means to receive pull forces being imposed on the busbar portion in a direction opposite to a mating direction. The plug connector housing has a corresponding retention means that engages with the retention means when the busbar portion is at least partially accommodated in the plug connector housing.

An electrical connector comprises a housing body with a peripheral region and a central region. A hinge support protrudes from the housing body. A curved wall portion extends outward from the central region. A lid has a hollow portion arranged for rotation with respect to the hinge support. A spring or resilient member is configured to bias the lid in a closed state against an electrical socket with one or more electrically conductive terminals in an interior of the electrical socket. A slider is arranged to slide radially along the curved wall portion between an open position and a closed position, where the closed position holds the lid in the closed state and where the open position allows the lid to be rotationally raised or flipped upward.

A plug connector housing having a housing, a sleeve arranged movably relative to the housing, and a lever, the lever being mounted on the housing for rotation about an axis of rotation extending perpendicularly to a plug-in direction of the plug connector housing, wherein the sleeve can be displaced in the plug-in direction in order to fix a cable by a rotary movement of the lever and the plug connector housing can be locked with a mating plug connector housing by the rotary movement of the lever, the housing having a cable-side end and a plug-side end and a strain relief element having an opening for passing through a cable being arranged at the cable-side end of the housing, and it being possible for the sleeve to at least partially be pushed onto the strain relief element in order to exert radial pressure on the strain relief element relative to the plug-in direction.

A connector arrangement includes a plug nose body; a printed circuit board positioned within a cavity of the plug nose body; and a plug cover that mounts to the plug nose body to enclose the printed circuit board within the cavity. The printed circuit board includes a storage device configured to store information pertaining to the electrical segment of communications media. The plug cover defines a plurality of slotted openings through which the second contacts are exposed. A connector assembly includes a jack module and a media reading interface configured to receive the plug. A patch panel includes multiple jack modules and multiple media reading interfaces.

A traction battery assembly according to an exemplary aspect of the present disclosure includes a traction battery, an electric machine, an electrical harness assembly, a protrusion adjacent the electrical harness assembly. The protrusion is configured to move from a first position to a second position in response to a loading event. When the protrusion is in the first position, the electric machine is electrically coupled to the traction battery through the electrical harness assembly. When the protrusion is in the second position, the electric machine is electrically decoupled from the traction battery.

A ganged connector assembly includes: a plurality of coaxial connectors, each of the coaxial connectors connected with a respective coaxial cable extending rearwardly therefrom, each of the coaxial connectors including an inner contact and an outer body that is electrically separated from the inner contact; a shell having a plurality of cavities; and a plurality of rear bodies, each of the rear bodies encircling a respective outer body, each of the rear bodies mounted in a respective cavity of the shell. Each of the rear bodies includes a first locking feature. A second locking feature is located in each of the cavities and is fixed relative to the shell. The first and second locking features are configured such that rotation of a first of the plurality of rear bodies relative to the shell moves the first rear body between locked and unlocked positions, wherein in the locked position a respective first connector and respective first cable are secured with the shell within a respective cavity, and in the unlocked position the first connector and first cable can be removed from the shell without removing the remaining connectors and cables.