An electrical connector system for electrically and mechanically connecting with a component in a motor vehicle is disclosed. The connector system includes a motor vehicle component and a male connector assembly with a male housing that receives a male terminal. This terminal includes a receiver and side walls with a contact arm that extends across an aperture in the side wall. An internal spring member with at least one spring arm resides within the male terminal receiver. A female connector assembly includes a female terminal with a receptacle that receives both the male terminal and the spring member. A female housing receives the female terminal and an extent of the male connector assembly. When the connector system moves from the partially assembled state to a connected position for connection of the vehicle component, the male connector assembly is inserted into female housing, the contact arm is brought into sliding engagement with an angled internal segment of the female housing, and the contact arm is inwardly displaced as the contact arm slidingly engages with the angled internal segment.

An electrical connector and a method for fastening the connector to a circuit board has a connecting chamber in which a conductor rail is arranged. The conductor rail is electrically connected at a connecting side of the electrical connector to an electrical connecting part make electrical contact at a contact side with a circuit board. The conductor rail includes a connecting arm for connection with the electrical connecting part and a contact arm for connection with the circuit board. The connecting arm and the contact arm are joined together by a connection arm. The connecting part is displaced in a connecting direction extending parallel to the conductor rail for connection with the conductor rail. The contact arm is designed as a spring in order to press against the circuit board when they are connected. The conductor rail can be positioned in two mutually rotated positions and the electrical connector may have at least two adjacent connecting chambers.

The present disclosure relates to a power connector which comprises an insulative housing and a terminal. The insulative housing defines a terminal receiving groove therein and comprises a stopping wall. The terminal is positioned in the terminal receiving groove and comprises a mating portion, a stopping portion and a wire connecting portion. The stopping portion abuts against the stopping wall and comprises a first horizontal portion and a second horizontal portion. The first horizontal portion comprises a first front end edge. The second horizontal portion comprises a second front end edge. A portion of a front end of the first horizontal portion and a portion of a front end of the second horizontal portion are cut off, therefore when the terminal clamps the wire, the first front end edge and the second front end edge do not splay forwardly and outwardly to protrude forwardly, but are parallel to each other or respectively extend backwardly, which thus can avoid the first front end edge and the second front end edge of the stopping portion from abutting against the stopping wall first due to the protruding.

A connector includes a housing, a first sandwich structure, and a support structure. The housing includes two accommodating cavities vertically adjacent to each other, where each accommodating cavity is used for receiving a docking connector. The first sandwich structure is disposed between the two accommodating cavities. The support structure penetrates two side walls of the housing and two side walls of the first sandwich structure to fix the first sandwich structure on the housing.

A connector assembly includes multiple terminals. Each terminal includes a conductive portion. The terminals include first and second high speed signal terminals and a low speed signal terminal. The conductive portions of the first and second high speed signal terminals and the low speed signal terminal are correspondingly defined as first, second and third conductive portions. An adapter board is located above a circuit board to be conductively connected to a cable directly or indirectly. The adapter board includes first and second signal circuit layers located at different heights. The first signal circuit layer includes a first high speed signal circuit conductively connecting the first conductive portion and a conductive wire of the cable. The second signal circuit layer includes a second high speed signal circuit conductively connecting the second conductive portion and another conductive wire of the cable. The third conductive portion is conductively connected to the circuit board.

A cable socket connector assembly for an electronic system includes a socket assembly having a socket substrate including socket substrate conductors. The socket assembly has socket contacts extending between terminating ends and mating ends with the terminating ends terminated to corresponding socket substrate conductors and the mating ends configured to be terminated to corresponding package contacts of an electronic package of the electronic system. The cable socket connector assembly includes a cable assembly terminated to the socket assembly having an array of cables each having a cable conductor terminated to a corresponding socket substrate conductor. The socket contacts and the corresponding socket substrate conductors define electrical paths between the cable conductors of the cables and the package conductors of the electronic package.

A socket connector includes a socket assembly having a socket frame, a socket substrate coupled to the socket frame and socket contacts terminated to the socket substrate. The socket substrate has first and second upper mating areas including first and second socket substrate conductors for mating with an electronic package and an electrical component, respectively. The socket contacts define an interface with the electronic package. The socket assembly is configured to electrically connect the electronic package with both a host circuit board and the electrical component.

An electrical connector assembly for electrically and mechanically connecting a component to a power source is disclosed. The connector assembly includes a male terminal with side walls defining a receiver. The side wall includes a contact arm that extends across an aperture in the side wall. The assembly also includes an internal spring member dimensioned to reside within the receiver of the male terminal. The spring member has at least one spring arm that extends from a base portion. The assembly further includes a female terminal with a receptacle dimensioned to receive both the male terminal and the spring member residing within the receiver of the male connector to define a connected position. In the connected position, the spring arm exerts an outwardly directed biasing force on the contact arm of the male terminal to outwardly displace it into engagement with an inner surface of the receptacle to ensure connectivity.

A socket connector includes a socket assembly having a socket substrate and socket contacts. The socket substrate has first and second upper mating areas and a first lower mating area. The socket substrate has first and second socket substrate conductors at the first and second upper mating areas, respectively, and third socket substrate conductors at the first lower mating area electrically connected to corresponding first socket substrate conductors. The first socket substrate conductors are electrically connected to an electronic package, the second socket substrate conductors are electrically connected to an electrical component and the third socket substrate conductors are electrically connected to a host circuit board. The socket assembly is configured to electrically connect the electronic package with both the host circuit board and the electrical component. The socket contacts have a terminating end terminated to corresponding first socket substrate conductors and a mating end mated to package contacts.

The present disclosure relates to a power connector which comprises an insulative housing and a terminal. The insulative housing defines a terminal receiving groove therein and comprises a stopping wall. The terminal is positioned in the terminal receiving groove and comprises a mating portion, a stopping portion and a wire connecting portion. The stopping portion abuts against the stopping wall and comprises a first horizontal portion and a second horizontal portion. The first horizontal portion comprises a first front end edge. The second horizontal portion comprises a second front end edge. A portion of a front end of the first horizontal portion and a portion of a front end of the second horizontal portion are cut off, therefore when the terminal clamps the wire, the first front end edge and the second front end edge do not splay forwardly and outwardly to protrude forwardly, but are parallel to each other or respectively extend backwardly, which thus can avoid the first front end edge and the second front end edge of the stopping portion from abutting against the stopping wall first due to the protruding.