A connector having a housing, a slide member, and an operation lever. The slide member slides in response to operation of the operation lever. The slide member has a guide projection and slides while the guide projection is guided in a guide groove of the housing. The slide member has a cam groove that receives a cam pin in a second connector and the slide member, by sliding, performs mating with the second connector. The slide member has a first nipping portion that nips the cam pin when it slides to a completely mated position. The housing has a second nipping portion that nips the guide projection of the slide member when the slide member slides to the completely mated position.

The present disclosure discloses an electric shock-proof plug that comprises an insulating sleeve, a plug body, and a reset member. The plug body is movably disposed in the insulating sleeve. An inner wall of the insulating sleeve comprises a guiding groove, and an outer wall of the plug body comprises a sliding member movably coupled to the guiding groove. The sliding member moves in the guiding groove to drive the plug body to move between a high position and a low position. When the plug body moves to the low position, a connector of the plug body is exposed out of the insulating sleeve, and the reset member generates an elastic resetting force. When the plug body moves to the high position, the connector is retracted back into the insulating sleeve. A user will be prevented from getting an electric shock when unplugging the electric shock-proof plug.

An electrical connector including: a magnetic element having a cavity; a contact protector movably accommodated in the cavity, the protector defining a front end and a plurality of slots through the front end; a plurality of contacts accommodated in the slots, each contact being retractable and having a front end located in the front end of the contact protector; and an elastic element urging the contact protector to extend the front end thereof out of the cavity.

Technologies for composing a managed node with multiple processors on multiple compute sleds to cooperatively execute a workload include a memory, one or more processors connected to the memory, and an accelerator. The accelerator further includes a coherence logic unit that is configured to receive a node configuration request to execute a workload. The node configuration request identifies the compute sled and a second compute sled to be included in a managed node. The coherence logic unit is further configured to modify a portion of local working data associated with the workload on the compute sled in the memory with the one or more processors of the compute sled, determine coherence data indicative of the modification made by the one or more processors of the compute sled to the local working data in the memory, and send the coherence data to the second compute sled of the managed node.

The present disclosure discloses a protection cover device for socket, which includes a housing, a protection cover which is arranged in the housing, and a torsion spring which is configured to reset the protection cover, the housing includes a bottom plate and a faceplate spaced apart from the bottom plate, the faceplate is provided with a first insertion hole and a second insertion hole, the bottom plate is provided with a first through hole and a second through hole; the protection cover is provided with a first driving slope and a second driving slope that guide the protection cover to translate along a distribution direction of the first insertion hole and the second insertion hole, the protection cover is further provided with a probe hole, and the torsion spring includes a spring body, a first swinging arm and a second swinging arm.

In a specific embodiment, a connector 100 is disclosed. The connector 100 comprises an insulative housing 102 defining a rear opening 108 for receiving a plurality of electrical wires 110 and a front opening 106 and a circuit board 104 disposed in the housing 102 and comprising a mating section 112 for mating with a corresponding mating section of a mating connector. The mating section 112 protrudes outwardly from the front opening 106 and terminates at a front edge 118 disposed between opposing side edges 114,116 of the mating section 112. The connector 100 further comprises opposing side arms 128,130 extending forwardly from opposing lateral sides 124,126 of the front opening 106 along, adjacent and beyond corresponding side edges 114,116 of the mating section 112 with a maximum separation between each side edge 114,116 and the corresponding side arm 128,130 being sufficiently small so that when the connector 100 mates with a mating connector, no portion of the mating connector can be inserted between the side edge 114,116 and the corresponding side arm 128,130. Other exemplary embodiments are also disclosed.

By a simple configuration, contact members can be well retained with a housing in a mutually opposed state, and productivity can be improved. When the contact members in the mutually opposed state are to be attached to the housing, a contact retainer prepared by molding in advance is used by disposing the contact retainer in part of the contact opposed region. As a result, the contact members are stably retained in the mutually opposed state even in injection molding molds. Even in a case in which the contact members normally cannot be retained in the mutually opposed state in the injection molding molds, the housing and the contact members can be integrally molded by well retaining the contact members in the mutually opposed state by using the contact retainer and a contact retainer auxiliary and executing an injection molding process.

A plug connector (100) includes: a sleeve (1) having a receiving cavity (11); and a terminal module (10) including a fixed body (7) received in the receiving cavity (11), an insulative housing (11) located in front of the fixed body (7) and extended beyond the sleeve (1), a magnetic element (6) received in the sleeve (1), a plurality of movable terminals (4), and plural elastic elements (5), the insulative housing (11) having a number of through holes (31), the other end of the elastic element (5) bearing against the fixed body (7), the movable terminals (4) in non-retracted state being located inwardly of the insulative housing (3), the insulative housing (3) being operable to move backwards urging against the elastic elements (5) and exposing the movable terminals (4) in retracted state out of the insulative housing (3); wherein the movable terminals (4) are sheathed in the elastic elements (5).

A docking station a first connector, a post, and a pop-out cover. The first connector is mounted to float within a first opening of a case of the docking station. The post is in physical communication with the case. The post provides a first alignment between the first connector and a second connector of an information handling system. The pop-out cover is in physical communication with the case and the post. The pop-out cover is biased in a first alignment stage, and transitions from the first alignment stage to a second alignment stage in response to a force exerted on the pop-out cover by a weight of the information handling system. The first connector is joined with the second connector in response to pop-out cover being placed in the second alignment stage.

An electrical receptacle including a body having a first cavity and a second cavity, a plurality of first electrical connections in the first cavity and a plurality of second electrical connections in the second cavity, at least one electrical plug sensing device in the first cavity, and wherein electrical continuity to the plurality of first electrical connections from the plurality of second electrical connections only occurs when the at least one electrical plug sensing device senses a presence of an electrical plug in the first cavity.