The present disclosure relates to the field of electrical connection of cables and the like, for all industries and in particular in the aeronautic or automotive industry. A single pass-through connector for connecting first cables and second cables disposed in respective first area and second area of a vehicle, the single pass-through connector having a frame body and a plurality of first communication network connectors for receiving portions of the first cables and of the second cables, each first communication network connector has a back portion and a front portion, and wherein each first communication network connector is arranged for receiving the corresponding first cable from the back portion, and for receiving the corresponding second cable from the front portion, so as to connect the corresponding first cable and the corresponding second cable together and pass-through a separation between the two areas.

A powered wall plate with at least two electrical plug prongs configured to removably mate with an electrical receptacle of an electrical device. A protruding front face extends from the front surface and has a plurality of electrical current apertures extending into the front face, which are configured to receive an electrical plug. A plurality of mounting screw apertures extend through the wall plate, configured to receive a plurality of mounting screws to attach the wall plate to the electrical device. One of the mounting screw apertures may be located on the front face. A spacer may be placed between the wall plate and the electrical device to close a gap. A plurality of LED lights is located along a bottom edge of the front surface, a photocell is exposed on the front surface of the wall plate, and a control switch has an on position, an off position, and an auto position. A circuit between the front face and a rear surface of the wall plate is operatively coupled to a USB port on a side surface of the front face. The USB port is configured to provide power when power is supplied to the at least two electrical plug prongs.

A system includes a jack screw including a body portion and a keyed portion extending along a length of the body portion. The system includes a panel including a first aperture configured to receive the jack screw. The system includes a connector including a second aperture configured to receive the jack screw. The system includes a plate including a third aperture configured to receive the jack screw, where the jack screw is configured to be aligned along an axis through the first aperture, the second aperture, and the third plate aperture, where a portion of the body portion of the jack screw extends past a locking plate.

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 connection device and a floating connection assembly are provided. The floating connection assembly includes a floating connector and an assembling module. The floating connector includes a floating module and a main body. The floating module defines an assembling region and a plurality of holding regions that are distributed around the assembling region. The main body is inserted into the assembling region of the floating module. The assembling module is retained by the floating module through the holding regions. The floating module and the assembling module are jointly configured to movably clamp a panel, and are jointly movable relative to the panel.

An electrical connection assembly and a floating connector are provided. The floating connector includes a floating module, a main body, and a plurality of elastic components. The floating module defines an active region therein, and the floating module has a plurality of thru-holes arranged outside of the active region. The main body is inserted into the active region of the floating module. The elastic components are disposed in the active region and are elastically deformable along an insertion direction. Two ends of each of the elastic components are respectively abutted against the floating module and the main body, so that the main body is movable along the insertion direction relative to the floating module through at least one of the elastic components.

A device connector 10 disclosed by this specification is a device connector 10 to be mounted on a case 1 of a device and includes a housing 20 fittable into a mounting hole 2 provided in the case 1, a wire 40 pulled out in parallel to an outer surface 4 of the case 1 from the housing 20, a shield member 50 including a wire-side mounting portion 53 and configured to cover the wire 40, and a connecting member (insert nut 60) configured to coaxially arrange and directly connect a case-side mounting portion 3 projecting in a direction intersecting a pull-out direction of the wire 40 from the outer surface 4 of the case 1 and the wire-side mounting portion 53.

A shield connection structure includes a shielded cable 20, a conductive interposing members 40 to be mounted on the shielded cable 20, a conductive inner shell 50 for covering the interposing member 40, a conductive annular outer shell 60 for covering the inner shell 50, and a retainer 80 made of synthetic resin and to be mounted in the outer shell 60. The interposing member 40 contacts an electromagnetic shield member 23 exposed from an insulation coating 24 and the inner shell 50 and electrically connects the electromagnetic shield member 23 and the inner shell 50. The inner shell 50 contacts the interposing member 40 and the outer shell 60 and electrically connects the interposing member 40 and the outer shell 60. The retainer 80 holds the inner shell 50 with the inner shell 50 held in contact with an inner surface of the outer shell 60.

Provided are embodiments for an electrical connector system. Embodiments include an electrical connector and a support ring where the support ring includes a baseplate having a first side and a second side, a recessed portion on a first side of a baseplate for a primary O-ring, and a sidewall extending from the second base plate. Embodiments also include a housing coupled to the support ring, wherein the sidewall extends into the housing, wherein the support ring is coupled to the electrical connector on the first side, and the support ring is coupled to the housing on the second side. Also provided are embodiments for the support ring and assembling the electrical connector system.

An electrical connection device for connecting a plug, preferably a HV pin header, to a printed circuit board in a motor vehicle, having the following: at least one first electrical connection-device for contacting at least one assigned plug-connector contact; at least one second electrical connection-device contact for contacting at least one assigned printed-circuit-board contact wherein at least one first connection-device contact at least one second connection-device contact are connected to one another, wherein the electrical connection device is configured in such a manner that at least one printed-circuit-board contact is able to be selectively connected to assigned plug-connector contacts which differ in terms of the relative disposal thereof in relation to the printed-circuit-board contact and/or differ from one another in that said plug-connector contacts are a component part of plug connectors which differ from one another in terms of the configuration of the respective plug-connector contacts thereof.