A jumper bus bar may include a frame and a terminal assembly. The frame is to be seated along a surface of a housing of an electrical box. The terminal assembly features a first fork terminal perpendicular to the frame and a second fork terminal perpendicular to the frame. The first fork terminal is adjacent the second fork terminal. The terminal assembly also includes a slot to receive a terminal of a fuse or relay, the slot being coplanar with the frame.

In a connector, movement of a contact is appropriately restricted in detaching a counter connector from the connector. The connector fittable with the counter connector in a first direction includes the contact and a housing. The contact includes: a press-fitted portion press-fitted into the housing in a second direction intersecting the first direction; an extension portion that extends from the press-fitted portion in a third direction intersecting the first and the second directions; and a contact portion that extends from the extension portion and contacts the counter contact. The housing includes a protrusion portion that protrudes from a rising portion in the third direction. In a state where the press-fitted portion is press-fitted in the housing, a surface of a distal end portion in the third direction of the extension portion contacts the protrusion portion, which surface faces a side where the counter connector is situated.

The present invention relates to an electrical plug connector for an electrical connection system. The electrical plug connector comprises a plug connector housing comprising a housing body and a busbar portion. The busbar portion is at least partially accommodated in the plug connector housing. The busbar portion includes a busbar conductor, and a busbar end which is integrally formed with the busbar conductor. The busbar end includes a connection portion that is configured for being plugged to a mating connector to establish an electrical connection. The busbar end further includes a retention means which is configured to engage with a corresponding retention means to receive pull forces being imposed on the busbar portion in a direction opposite to a mating direction. The plug connector housing has a corresponding retention means that engages with the retention means when the busbar portion is at least partially accommodated in the plug connector housing.

The present disclosure provides a connector, which relates to the technical field of electrical connection devices, so as to solve the problem of poor connection stability of connectors in existing technologies. The connector includes a mounting base and a binding post, wherein the binding post has both sides symmetrically provided with a fixed fin, the mounting base defines thereon a mounting groove for mounting the binding post, two sides of the mounting groove define a limit groove, and the fixed fin is clamped in the limit groove so as to enable the binding post to be limited to the mounting groove. The connector according to the present disclosure has good connection stability and can effectively transmit current or signal, enabling an effective cooperation between connected devices.

The connector 10 includes a movable housing 40 that is displaceable with respect to an attachment object 90 in an X direction, which is a direction perpendicular to a connection direction, and a terminal 20 configured to electrically connect the attachment object 90 and a connection object 80. The terminal 20 includes the displacement portion 24 that is displaceable in the X direction with respect to the attachment object 90. The contact portions 24c1 and 24f1 configured to contact the connection object 80 are formed in the displacement portion 24. Here, the displacement portion 24 is displaceable with respect to the movable housing 40.

A connector is mateable with a mating connector. The connector comprises a housing and a terminal. The terminal has an arm, a contact portion and a held portion held by a holding portion of the housing. The arm couples the held portion and the contact portion to each other and supports the contact portion so that the contact portion is movable. The contact portion has a bottom portion, a first support portion, a second support portion, a first contact point and a second contact point. Each of the first support portion and the second support portion extends upward from the bottom portion. The first contact point is supported by the first support portion. The second contact point is supported by the second support portion. Under a mated state, a mating terminal of the mating connector is sandwiched and held between the first contact point and the second contact point.

An electrical junction box includes a frame body, a rescue terminal portion formed in a rectangular parallelepiped shape in a plan view and including a longitudinal side face, two lateral side faces connected to the longitudinal side face, and an upper face, a resin cover configured to cover the longitudinal side face, the two lateral side faces and the upper face. The resin cover includes a rotary shaft extending along the longitudinal side face and provided on a side where the longitudinal side face is provided and on a base end portion of the rescue terminal portion opposite to the upper face, the resin cover being configured to rotate with respect to the frame body about the rotary shaft.

An electrical connector pin having a link segment for linking to the connector and an end segment that is free, the end segment having a cross-section that is flat and being provided with a slot passing through the end segment in its thickness direction and extending over a length of the free end segment to form two mutually parallel blades, each having a first edge that is straight beside the slot and a second edge extending remotely from the slot and that is provided with a contact portion projecting laterally relative to an outside surface of the link segment, the blades being elastically deformable transversely so as to vary the width of the slot. A connector and an electronic device including such a pin.

An aspect of the present disclosure is directed to a connector. The connector is suited to connectorizing exactly two conductors. The connector includes a forward connector body, a rear connector body, a metal frame and exactly two electrical contacts. The rear connector body interfaces with the forward connector body. Further, the metal frame, which includes a shielding interface, surrounds at least a portion of both the forward and rear connector bodies. The electrical contacts extend from the rear connector body into the forward connector body. A first of the electrical contacts is electrically coupled to a first conductor of a shielded cable and the second of the electrical contacts is electrically coupled to a second conductor of the shielded cable. The shield interface of the metal frame is electrically coupled to the shield of the shielded cable.

A socket (10) includes a first insulator (20), a second insulator (30), contacts (50), and a pair of metal fittings (40). The socket (10) is in the form of a frame. The second insulator (30) is located within the first insulator (20). The contacts (50) are supported by the first insulator (20) and are disposed within the second insulator (30) movable relative to the first insulator (20). Each metal fitting of the pair of metal fittings (40) is provided to the corresponding one of two ends of the first insulator (20) that are opposite in an arrangement direction of the contacts (50). The metal fittings (40) each include a base (41) supported by the first insulator (20). The metal fittings (40) each include a biasing portion (42) and a contacting portion (43). The biasing portion (42) projects from the base (41) and extends toward the second insulator (30). The contacting portion (43) is provided to the biasing portion (42) and is in contact with the second insulator (30). The pair of metal fittings (40) is disposed in such a manner that the second insulator (30) is fitted between the contacting portions (43) of the metal fittings (40) in the arrangement direction.