A connector release assist system includes a first connector that has at least one first connector securing feature that is configured to engage a second connector to secure the second connector to the first connector, and disengage the second connector when a second connector release member on the second connector is actuated. A subsystem is located adjacent the first connector such that the subsystem inhibits access to the second connector release member when the second connector is secured to the first connector. A connector release assist device is located adjacent the first connector, extends past the subsystem, and is configured to actuate the second connector release member. In specific examples, the first connector is an RJ-45 female connector, and the second connector is an RJ-45 male connector.

A connector system with a primary connector and a coupling connector, and a method for connecting a coupling connector and a primary connector. The system provides an insertion aid for mating the connectors. The connector system has a primary connector with a connecting part and a coupling connector with a base unit and a connecting part. The coupling connector has a slider part that moves relative to the base unit to either a preliminary position or a final position. The connecting part of the coupling connector mates with the connecting part of the primary connector. The slider part and the primary connector each have at least one guiding component which both interact to enforce a predefined motion path of the slider part relative to the primary connector when the coupling connector is coupled with the primary connector and the slider part is moved from the preliminary position to the final position.

Embodiments disclosed herein relate to a high frequency connector system with reduced stub lengths that provide improved performance at high frequencies. A first connector includes a plurality of mating contacts designed to electrically connect to a second plurality of mating contacts associated with a second connector. The first connector includes one or more elastic members such that when the second connector is mated to the first connector, the one or more elastic members are compressed between the first and second connectors. The first and second plurality of contacts overlap by a first distance when initially mated, but when the connectors are released, the first elastic member biases the second connector away from the first connector such that the first and second plurality of contacts overlap by a second distance smaller than the first distance.

A modular connector includes a connector body and a locking part. The connector body has a surface. The locking part includes a connection portion and a retaining portion connected to the connection portion. The connection portion is rotatably connected to the surface relative to a direction. The direction is perpendicular to the surface. The locking part is rotatable to engage with a retaining structure of a mating modular connector.

A connector structure (3) includes a first connector (1) and a second connector (2). The outer housing (10) of the first connector (1) has: a lock mechanism (12) to be engaged with a counterpart housing (60) of the second connector (2) to restrict a rearward movement of the counterpart housing (60) in the fitting direction when fitting the first connector (1) and the second connector (2); a first unlocking mechanism (14) configured to disengage a lock mechanism (12) for the counterpart housing (60); and a second unlocking mechanism (18) located at a different position than the first unlocking mechanism (14) and configured to disengage the lock mechanism (12) independently of the first unlocking mechanism (14).

The prevent invention relates to connector fields, and more particularly, to an engagement structure of Ethernet connector for vehicle. The plug and the socket are combined and engaged; the plug shell mounted around an outer periphery of the male terminal assembly; the plug shell including a lock plate and a lock seat. When the plug is combined with the cable end socket, the plug shell is inserted into the cable end socket shell, with the circular male terminal combined with the circular female terminal. When the lock plate is pushed from the second end toward the first end of the rail, the ramp elastically crosses over the second end of the bolt member to be engaged between the ramp and the protrusion, and the hook member is engaged with the outer hook.

The present disclosure discloses a socket connector including an insulating base and a number of socket terminals. The insulating base includes an outer plastic frame defining a receiving channel and an inner plastic block received in the receiving channel. The inner plastic block includes two sidewalls opposite to each other in a left-and-right direction. The socket terminals are arranged in two rows by positioning symmetrically and respectively on the two sidewalls of the inner plastic block. The socket terminals of each row are arranged in an upper-and-lower direction and spaced away from each other in the upper-and-lower direction. Each socket terminal extends along a front-and-back direction perpendicular to both the left-and-right direction and the upper-and-lower direction. A connector assembly including the socket connector and the mated plug connector is also disclosed in the present disclosure.

Embodiments disclosed herein relate to a high frequency connector system with reduced stub lengths that provide improved performance at high frequencies. A first connector includes a plurality of mating contacts designed to electrically connect to a second plurality of mating contacts associated with a second connector. The first connector includes one or more elastic members such that when the second connector is mated to the first connector, the one or more elastic members are compressed between the first and second connectors. The first and second plurality of contacts overlap by a first distance when initially mated, but when the connectors are released, the first elastic member biases the second connector away from the first connector such that the first and second plurality of contacts overlap by a second distance smaller than the first distance.

In one embodiment, an apparatus includes a connector plug for attachment to a single pair Ethernet cable comprising a pair of conductors, and configured for being received in a connector receptacle. The connector plug includes a first end for receiving the single pair Ethernet cable and a second end having a pair of contacts, each of the contacts comprising a receptacle contact interface, a conductor interface, and an extension to provide an increased width between conductor gripping prongs at the conductor interface while maintaining a consistent spacing between the pair of contacts at the receptacle contact interface with connector plugs configured to mate with different gauge cables. The connector plug comprises a latch for secure attachment to the receptacle and a pull cord connected to the latch and accessible when the connector plug is inserted into the receptacle with other connector plugs for release of the connector plug.

The present disclosure discloses a plug connector including an insulating housing, a number of plug terminals and a cable. The insulating housing includes a width direction extending along a left-and-right direction. The plug terminals are retained by the insulating housing and arranged in two rows in the width direction of the insulative housing. The plug terminals of each row are arranged in an upper-and-lower direction and spaced away from each other in the upper-and-lower direction. Each plug terminal extends along a front-and-back direction. The cable includes a number of core wires correspondingly and electrically connected with the plug terminals. A connector assembly including the plug connector and the mated socket connector is also disclosed in the present disclosure.