A connection assembly for the electrical and mechanical connection between a contact electrode and an electrical conductor element has a flexible sensor/electrode section in which the contact electrode is at least partially arranged. The connection assembly has at least one electrical inner conductor of the electrical conductor element for applying and/or removing an electrical voltage and/or capacitive change at the contact electrode. An electrical contact region is provided in which the at least one electrical inner conductor makes electrical contact with the contact electrode of the sensor. A connecting device is provided which can be prestressed against the contact electrode of the sensor in the contact region, with interposition of the inner conductor.

A cable connector includes a number of cables and an electrical connector. Each cable includes a core wire, an insulating layer wrapped on the core wire and a shielding layer wrapped on the insulating layer. The electrical connector includes an insulating body, a number of conductive terminals and a shielding shell. Each conductive terminal includes a contact portion for mating with a mating connector and a tail portion connected with the core wire. The cable connector further includes a ground shield mounted to the cables. The ground shield is connected with the shielding layers of the cables, and the ground shield is connected with the shielding shell. Compared with the prior art, the present disclosure improves the shielding performance of the cable connector by providing connecting the ground shield, the shielding layers and the shielding shell together.

A cable connector includes a number of cables and an electrical connector. Each cable includes a core wire, an insulating layer wrapped on the core wire and a shielding layer wrapped on the insulating layer. The electrical connector includes an insulating body, a number of conductive terminals and a shielding shell. Each conductive terminal includes a contact portion for mating with a mating connector and a tail portion connected with the core wire. The cable connector further includes a ground shield mounted to the cables. The ground shield is connected with the shielding layers of the cables, and the ground shield is connected with the shielding shell. Compared with the prior art, the present disclosure improves the shielding performance of the cable connector by providing connecting the ground shield, the shielding layers and the shielding shell together.

Connectors that support high-speed data transfers and have a high signal quality, good reliability, and are readily manufactured. One example can provide a connector receptacle that supports high-speed data transfers and has a high signal quality by employing contacts that are directly attached to a flexible circuit board.

Connectors that support high-speed data transfers and have a high signal quality, good reliability, and are readily manufactured. One example can provide a connector receptacle that supports high-speed data transfers and has a high signal quality by employing contacts that are directly attached to a flexible circuit board.

A receptacle connector includes a metal housing configured to prevent backwards insertion of a plug. The receptacle connector has walls bounding an assembly space with an insulative body therein. One wall is distant from an exterior surface of the insulative body to form an abutting groove between the metal housing and the insulative body. The abutting groove is configured to receive an abutting wall of the plug connector. The insulative body includes mating interface configured to receive a terminal portion of a plug connector. A wall of the metal housing opposite the abutting groove is adjacent a surface of the insulative body has a projection. If a user attempts to insert the plug with the terminal portion backwards, the projection interferes with the abutting wall, preventing backwards insertion of the terminal portion of the plug into the mating interface.

A first connector, a second connector and an electrical connector assembly having the first connector and the second connector are provided. The first connector includes an insulating housing and a locking plate embedded in the insulating housing, and a plurality of first power terminals, a plurality of first signal terminals and a plurality of first braking terminals mounted in the insulating housing; the locking plate is provided with a locking mechanism protruding upwardly. The second connector includes a terminal block, a cover body covering the terminal block, a locking slidable cover slidably mounted on the cover body and a plurality of second power terminals, a plurality of second signal terminals and a plurality of second braking terminals mounted in the terminal block. The locking slidable cover is capable of sliding forwardly and rearwardly relative to the cover body, and is capable of being locked together with the locking mechanism. It is adapted to a servo motor, saves space and is easy to assemble.

A first connector, a second connector and an electrical connector assembly having the first connector and the second connector are provided. The first connector includes an insulating housing and a locking plate embedded in the insulating housing, and a plurality of first power terminals, a plurality of first signal terminals and a plurality of first braking terminals mounted in the insulating housing; the locking plate is provided with a locking mechanism protruding upwardly. The second connector includes a terminal block, a cover body covering the terminal block, a locking slidable cover slidably mounted on the cover body and a plurality of second power terminals, a plurality of second signal terminals and a plurality of second braking terminals mounted in the terminal block. The locking slidable cover is capable of sliding forwardly and rearwardly relative to the cover body, and is capable of being locked together with the locking mechanism. It is adapted to a servo motor, saves space and is easy to assemble.

The seal spring of the present invention has a dual functionality. The seal spring provides both a sealing property and spring function in use within an electrical connector system, which is accomplished by its elastomeric qualities. The seal spring is preferably comprised of Silicone, EPDM rubber or materials and compositions that provide similar performance during use, or the like. The seal spring of the present invention is not limited or defined into a spring section or a seal section by its geometry. Shown is an implementation of the seal spring within an outer housing and connector assembly. The seal spring compresses and provides adequate spring force against a tab or tabs within the outer housing. The seal spring also functions as an interface seal and an environmental seal during use. The seal spring is, substantially, in its entirety, of a contiguous and continuous single construction. No part or section of the seal spring is made up of welded, soldered, or brazen part or section.

A backplane connector includes a housing and a number of terminal modules. Each terminal module includes a number of conductive terminals, a metal shield surrounding member, a first metal shield and a second metal shield. The conductive terminal includes a mating portion and a tail portion. The conductive terminals include a first signal terminal and a second signal terminal. The metal shield surrounding member surrounds the mating portions of the first signal terminal and the second signal terminal. The first metal shield and the second metal shield are in contact with the metal shield surrounding member. As a result, the shielding area is increased and the shielding effect is improved.