A plug connector includes a plug housing including a mating end and a cable end oriented perpendicular to the mating end. The plug connector includes a contact assembly having right angle contacts. A latch is coupled to the plug housing having a main body and a latch member extending from the main body. The latch member includes a pivot point. The plug connector includes a pull tab coupled to the main body of the latch at a connection point. The connection point is located forward of a pivot point and above a pivot point. The pull tab pulls on the main body at the connection point to pivot the latch at the pivot point to rotate the main body and the latch member in a downward actuation direction. The pull tab is pulled to release the latching tab from the mating connector.

A plug connector includes a plug housing including a mating end and a cable end oriented perpendicular to the mating end. The plug connector includes a contact assembly having right angle contacts. A latch is coupled to the plug housing having a main body and a latch member extending from the main body. The latch member includes a pivot point. The plug connector includes a pull tab coupled to the main body of the latch at a connection point. The connection point is located forward of a pivot point and above a pivot point. The pull tab pulls on the main body at the connection point to pivot the latch at the pivot point to rotate the main body and the latch member in a downward actuation direction. The pull tab is pulled to release the latching tab from the mating connector.

A rotatable power strip outlet assembly that includes a power strip housing, a plurality of electrical sockets formed on a front surface of the power strip housing, and a rear plug support member rotatably coupled to the power strip housing, that includes a front surface, a rear surface, and an electrical plug disposed on the rear surface of the rear plug support member and with electrical prongs extending outwardly away from the rear surface of the rear plug support member and electrically coupled to the plurality of electrical sockets, wherein the power strip housing is operably configured to selectively rotate at least 270° with respect to the rear plug support member to reorient the power strip housing while plugged into an electrical outlet.

A power supply device of a motor-driven child seat for a vehicle is provided. The motor-driven child seat can be easily mounted and fixed to a rear seat by adopting a method where a latch of the motor-driven child seat is fastened to an anchor of the rear seat, and power can be easily supplied to power consuming components, i.e., an electric mechanism including a motor, a ventilation system, and a heating system, by automatically fastening male-female connectors for supplying power, especially when the motor-driven child seat is fixedly mounted on the rear seat.

Provided is a connector. The connector is configured to electrically connect a docking element to a circuit board. The connector includes an insulation body, a pogo pin, a clip, a hook member, and a metal casing. The insulation body includes a base and a plug-in portion disposed at one end of the base. The plug-in portion is provided with a slot for accommodating the docking element. The pogo pin is disposed on the insulation body, where one end of the pogo pin is accommodated in the slot, and another end of the pogo pin is exposed outside the base. The clip is disposed on the plug-in portion, and part of the clip extends into the slot to abut the docking element.

Embodiments are generally directed to a snap button fastener providing electrical connection. An embodiment of a fastener includes a first mechanical part, the first mechanical part including at least a stud portion, the first mechanical part including a first electrical connector; a second mechanical part, the second mechanical part including at least a socket portion with a spring element and the socket portion, the second mechanical part including a second electrical connector. The stud portion of the first mechanical part and the socket portion of second mechanical part, if separated, are to interlock upon the application of a first force towards each other, and, if interlocked, to separate upon the application of a second force away from each other. The first electrical connector and the second electrical connector are to be electrically connected when the first mechanical part and the mechanical part are interlocked, and first electrical connector and the second electrical connector are to be disconnected when the first mechanical part and second mechanical part are separated.

Embodiments are generally directed to a snap button fastener providing electrical connection. An embodiment of a fastener includes a first mechanical part, the first mechanical part including at least a stud portion, the first mechanical part including a first electrical connector; a second mechanical part, the second mechanical part including at least a socket portion with a spring element and the socket portion, the second mechanical part including a second electrical connector. The stud portion of the first mechanical part and the socket portion of second mechanical part, if separated, are to interlock upon the application of a first force towards each other, and, if interlocked, to separate upon the application of a second force away from each other. The first electrical connector and the second electrical connector are to be electrically connected when the first mechanical part and the mechanical part are interlocked, and first electrical connector and the second electrical connector are to be disconnected when the first mechanical part and second mechanical part are separated.

A board-to-board connector assembly includes first and second connector assemblies and a connector interconnect between the first and second connector assemblies. Each connector assembly includes an outer shell and a connector received in a cavity of the outer shell. The connector has a connector body holding contacts in a card slot, which receives a circuit card edge of an add-in card. The outer shell has an outer board guide configured to engage the add-in card and guide mating of the outer shell with the add-in card. The outer shell has a latch configured to latchably engage the add-in card to secure the connector to the add-in card. The connector interposer electrically interconnects the contacts of the connector assemblies to electrically connect the add-in cards.

An electrical cable connecting system includes a modular electrical or electronic wiring device assembly, in which an electrical or electronic wiring device and a connector may be electrically coupled via pig-tail jumper electrical wires. The connector may be coupled to cable electrical wires fitted with a cable protector to protect the electrical wire conductors therein. The connector may include internal electrical terminals for electrically coupling building electrical cable wires with corresponding jumper electrical wires. The connector may be mechanically and electrically coupled to and directly terminate one or more building electrical cables, which may provide power to or from one or more electrical or electronic wiring devices by establishing an electrical pathway from a source of electrical power, through the building electrical cable wires, the connector, the pig-tail jumper electrical wires and an electrical or electronic wiring device.

An electronic module for a modular patient care system is disclosed. The electronic module can include a housing having an attachment side configured to releasably attach to an adjacent electronic module. A latch mechanism can be configured to engage a catch member on the adjacent electronic module to secure the attachment side to the adjacent electronic module. An electrical connector positioned on the attachment side can be configured to electrically connect to an adjacent electrical connector on the adjacent electronic module. A sensor coupled to the housing can be configured to detect movement of the latch mechanism indicative of at least one of engagement or disengagement of the latch mechanism from the adjacent electronic module.