A contact for a wire-to-wire electrical connector includes a first contact portion defining a first wire receiving opening to receive a first wire and a second wire receiving opening to receive a second wire. The contact further includes a splice contact portion abutting the first contact portion and defining a third wire receiving opening to receive a third wire. The first contact portion also includes a first plurality of contact tines to electrically connect the first wire and the second wire and the splice contact portion includes a second plurality of contact tines to electrically connect the third wire to the first wire and the second wire.

A connector assembly includes an outer conductive body having a first end configured to mate with a corresponding electrical connector, and a conductive center contact arranged within the outer conductive body. The center contact comprises a first end configured to mate with the corresponding electrical connector and a second end electrically connecting with a first electrical contact of a circuit board. An outer contact is slidably attached to a second end of the outer conductive body and electrically connects with a second electrical contact of the circuit board. An elastic element is provided for biasing the outer contact in a direction away from the outer conductive body and toward the circuit board.

A connector component and an electronic device related to the field of connector technologies, to resolve a problem that the connector component does not support slow hot insertion or removal. The connector component includes a first connector and a second connector. The first connector includes a first housing and a first conductive terminal. The first conductive terminal is fastened to the first housing. The second connector includes a fastening component and a movable component. The fastening component includes a second conductive terminal. The movable component includes a sliding terminal and a stopper. The sliding terminal is connected to the second conductive terminal in a sliding manner. The stopper is fastened to the sliding terminal. The second connector further includes a force accumulator. The force accumulator is connected to the fastening component and the movable component.

A header power connector includes a header housing assembly including an outer housing having cavities that receive corresponding inner housings, which hold terminals for electrically connecting upper and lower busbars. The inner housings are movable relative to the outer housing to accommodate misalignment of the corresponding upper and lower busbars. The terminals are movable in the terminal channels of the inner housings to accommodate misalignment of the corresponding upper and lower busbars.

An electrical power connector includes a connector housing having a receptacle receiving an elongated DC power distribution busbar, a first spring contact element arranged at a first side of the receptacle and pressed with a contact area to a first surface of the elongated DC power distribution busbar, and a second spring contact element pressed to a second surface of the elongated DC power distribution busbar opposite the first surface. The second spring contact element is arranged at a second side of the receptacle opposite to the first side. The power connector includes a temperature sensing device arranged inside the connector housing and monitoring a temperature at the first spring contact element and/or the second spring contact element.

An electrical outlet device includes water-resistant components to prevent the ingress of water to electrical components. One example includes a faceplate having a front surface, an outer edge extending around the front surface, and a first outlet opening extending through the front surface. A water-resistant seal is connected to the front surface of the faceplate. The seal has a first slit aligned with the first opening, a first flap adjacent the slit, and a second flap adjacent the slit. The first flap and the second flap are resiliently biased to a closed position and are moveable upon insertion of a plug.

An electrical outlet device includes water-resistant components to prevent the ingress of water to electrical components. One example includes a faceplate having a front surface, an outer edge extending around the front surface, and a first outlet opening extending through the front surface. A water-resistant seal is connected to the front surface of the faceplate. The seal has a first slit aligned with the first opening, a first flap adjacent the slit, and a second flap adjacent the slit. The first flap and the second flap are resiliently biased to a closed position and are moveable upon insertion of a plug.

The present disclosure relates to a card socket for an electronic device and, more particularly, to a card socket for an electronic device having an improved card insertion confirmation structure, wherein the structure of a card insertion confirmation terminal, which senses full insertion of a card or a tray into a card socket, is changed so as to improve stability of insertion of the card or the tray.

The present disclosure relates to a card socket for an electronic device and, more particularly, to a card socket for an electronic device having an improved card insertion confirmation structure, wherein the structure of a card insertion confirmation terminal, which senses full insertion of a card or a tray into a card socket, is changed so as to improve stability of insertion of the card or the tray.

At least two cascaded chains of intelligent support boxes linked by optical cable provide the needed elements to link the electric AC power line and low voltage DC power lines to the many known outlets and switches (wiring devices) and their loads be it AC or DC operated, with the AC and DC lines are separately drawn through separated conduits and ducts safely and accurately controlled by an home controller and/or via a command converter and a distributor.