A connector for use in a free-standing connector port for mating with an external pluggable module is disclosed. The connector has terminals that extend lengthwise of the connector so that cables may be terminated to the terminals and the terminals and cable generally are horizontally aligned together. The connector includes a housing and a pair of connecting elements that flank a card-receiving slot of the connector. The cables exit from the rear of the connector elements and from the connector port. The connector elements engage the connector port to fix the connector in place within the connector port.

A cable connector assembly includes: an electrical connector; and a cable electrically connected with the electrical connector, the cable including plural high-speed wires for transmitting high-speed signal, a pair of low-speed wires for transmitting low-speed signal, a pair of power wires for transmitting power signal, a pair of standby wires, a detection wire for transmitting detection signal, and a power supply wire; wherein the pair of standby wires, the detection wire, and the power supply wire are arranged in a line along a horizontal direction; the high-speed wires are evenly distributed on both sides of the line along a thickness direction vertical to the horizontal direction; the low-speed wires are disposed on a side of the line along the thickness direction; and the power wires are disposed on another side of the line along the thickness direction.

A surface mount electrical connector and methods of making and using a surface mount electrical connector. The connector includes a housing and a contact subassembly received in the housing. The contact subassembly includes interface contacts, board termination contacts, and an internal circuit board. The interface contacts and the board termination contacts are mounted to the internal circuit board to electrically connect the interface contacts and the board termination contacts through the internal circuit board. Each of surface mount tail ends of the board termination contacts has a bent portion that defines a mounting surface configured to be surface mounted to a mounting face of a main circuit board, to establish an electrical connection between the board termination contacts and the main circuit board.

A multi-way coupler includes a housing having at least three connector-receiving channels, a circuit board contained within the housing and at least three pairs of contacts including exactly one pair of contacts per each of the at least three connector-receiving channels. Each of the contacts includes a forward end extending into the respective connector-receiving channel and a rearward end electrically coupled to the circuit board. Further, each of the pair of contacts includes a first contact and a second contact with the circuit board including a first set of traces to electrically couple all of the first contacts together and a second set of traces to electrically couple all of the second contacts together. The multi-way coupler has a shielded configuration and a non-shielded configuration

An electrical wall plate may include one or more of the following features. A face plate comprising at least one electrical device opening extending through the face plate. At least one box mounting screw opening configured to receive at least one box mounting screw to fasten the face plate to an electrical device. A power connector extending in a direction away from the face plate and configured to connect with the electrical device. A camera integrated with the face plate and in electrical connection with the power connector and configured to operate by power obtained from the electrical device when the power connector is connected to the electrical device. A camera movement control feature may comprise externally-engageable components coupled to the face plate and configured to movably position the camera or a camera lens by pan or tilt to point in different directions.

A cable assembly comprising a connector with a termination that enables high density and high signal integrity. Shields of cables are terminated to a paddle card via a conductive structure attached to a surface of the paddle card. The signal conductors of the cables are terminated to pads on the paddle card that are exposed within openings of the conductive structure. Such a structure creates a ground structure per cable that provides low insertion loss and low crosstalk, even when multiple cables are aligned side by side and terminated in one or more rows. The cables may be drainless, enabling a large number of cables, such as eight cables, to be packed within the width of a paddle card specified in high density standards such as QSFP-DD or OSFP. The cables may nonetheless have large diameter signal conductors, enabling 2.5 or 3 meter assemblies with less than 17 dB insertion loss.

The present disclosure relates to a cable connector structure, which includes a housing, a tongue plate, a plurality of cables, and a plurality of heat sinks. The housing includes a docking end and a butting end. One side of the housing includes a top surface, and the top surface protrudingly provided with a hollow stage. The tongue plate is arranged in the housing, one end of the tongue plate is provided with a docking area, and the other end of the tongue plate is provided with a welding area. The plurality of heat sinks is arranged on the top surface of the housing, the hollow stage is arranged toward the docking end and the plurality of heat sinks are arranged toward the butting end.

The present invention discloses a smart electrical socket device enabling the detection of the temperature of the room in which it is installed; the device comprising a housing (1) essentially of a rectangular parallelepiped shape, where the front surface presents a female connection (6) enabling an external element (13) to be plugged in, and the rear surface includes pins (11) for the connection thereof to a power source; further incorporating a temperature module comprising a temperature sensor (2) disposed at the lower part of the internal metallic structure (10) and cut-outs (2.1) in the printed circuit board (PCB) (20) to isolate the heat produced by said board; a power consumption sensor circuit (4) disposed facing the printed circuit board (PCB) (20) and opposite the temperature sensor (2); a load actuator comprised of at least one relay; a power source (14); and a wireless communication module (5) disposed on the internal structure (PCB) (10).

A surgical stapling device includes a handle assembly, an adapter assembly, and a reload assembly that is releasably secured to the adapter assembly to facilitate replacement of the reload assembly after each use of the stapling device. The reload assembly includes an authentication chip and printed circuit board assembly that is constructed to provide electrical contacts that are self-supporting to allow for automated assembly of the electrical contacts and provide a more reliable, robust electrical connection between the electrical contacts and the chip.

A connector with a tolerance module includes a socket and a plug adapted to the socket, wherein the socket includes a first housing, the plug includes a tolerance module and a third housing, the tolerance module includes a second housing, the second housing includes second contact members, the second housing is movably arranged on the third housing in a direction perpendicular to the axial direction of the connector, and the second contact members are floatingly assembled in the second housing to enable displacement in the direction perpendicular to the axial direction of the connector. The second housing only generates translational motion without displacement when the connector is inserted. The tolerance of the plug and the socket is realized by the floating assembly of the second contact members in the second housing.