The invention relates to a direct plug-in connector (1) for establishing an electric connection between a conductor (30) and a metallized through opening (40) of a printed circuit board (50). The direct plug-in connector (1) has a fastening element (4) and a contact (2) with at least one first contact arm (3a). The first contact arm (3a) is configured for the electric connection of the conductor (30) to the metallized through opening (40). The fastening element (4) can assume a fastening position and a release position, the fastening element (4) being configured to fasten the direct plug-in connector (1) to the metallized through opening (40) in the fastening position.

Systems, apparatus, and/or processes directed to applying pressure to a socket to alter a shape of the socket to improve a connection between the socket and a substrate, printed circuit board, or other component. The socket may receive one or more chips, may be an interconnect, or may be some other structure that is part of a package. The shape of the socket may be flattened so that a side of the socket may form a high-quality physical and electrical coupling with the substrate.

An electrical connector assembly includes a housing defining an interior space and a slot and a spring pin terminal disposed within the slot of the housing. The spring pin terminal includes a first contact portion, a second contact portion, and an intermediate portion that extends between the first contact portion and the second contact portion. The first contact portion includes a contact point that engages a first electrically conductive structure and a retention force support that engages a portion of the intermediate portion of the spring pin terminal. The second contact portion includes a contact point that engages a second electrically conductive structure and a retention force and alignment support that engages the intermediate portion of the spring pin terminal.

An integral toolless-installation Compression Attached Memory Module (CAMM) bolster plate has a generally flat, parallelepiped body portion configured to contact one surface of a CAMM Printed Circuit Board (PCB) and provide compression between the CAMM and a z-axis compression connector. The bolster plate body defines (a) ramped keyhole(s), each ramped keyhole converts lateral displacement of the toolless-installation CAMM bolster plate into vertical displacement, providing the compression between the CAMM and the z-axis compression connector, by the ramped keyhole(s) sliding along (a) bottom face(s) of (a) head(s) of (a) fixed standoff(s) extending from an information handling system (IHS) PCB, through the z-axis compression connector and the CAMM PCB. The integral toolless-installation CAMM bolster plate may lock in place, laterally displaced, to maintain the compression between the CAMM and the z-axis compression connector. The integral toolless-installation CAMM bolster plate may also have a flange portion extending generally perpendicular from the body portion.

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 pluggable free-space photoelectric hybrid connector including a female connector and a male connector is provided. The female connector includes a first insulating substrate, metal elastic clips, a first circuit board, and a first optical communication module. An insertion cavity is formed at the front end of the first insulating substrate, and a first fiber mounting hole and first electrode mounting holes are formed at the rear end thereof. The metal elastic clips are mounted in the first electrode mounting holes respectively, where contact portions of at least one set of metal elastic clips are exposed from the top of the insertion cavity, and contact portions of at least another set of metal elastic clips are exposed from the bottom of the insertion cavity. The first circuit board is mounted at the rear end of the first insulating substrate and is electrically connected to the metal elastic clips.

A memory module testing system operating in a vibratory environment can retain a memory module in place in a memory socket using both socket latches and a retainer clip. The retainer clip can attach to a module support tower of the memory socket. The retainer clip can have a flexible multi-spring structure forming a three-axis vibration dampening system that can prevent the socket latches from opening while testing in the test environment. The retainer clip can secure the socket latches using an upper flange and a lower flange to prevent unintended motion of the socket latches. The retainer clip can be secured to the module support towers at the ends of the memory socket using clip arms and clip arm tips to attach to the module support towers.

An edge connector is configured to connect to a circuit board. The edge connector includes a base wall, a first terminal mount extending upwardly from the base wall, the first terminal mount having a plurality of passageways, terminals mounted in the passageways, a second terminal mount extending upwardly from the base wall, the second terminal being spaced from the first terminal mount, the second terminal mount having a plurality of passageways extending therethrough, terminals mounted in the passageways of the second terminal mount, and a moveable latch extending from the upper surface of the base wall, the latch positioned between the first and second terminal mounts. Each terminal mount extends along part of the length of the base wall such that a platform is formed by the upper surface of the base wall rearwardly of the terminal mounts. A latch protection wall extends from each terminal mount to the rear end of the base wall, and the latch protection walls are proximate to the latch.

A connector includes: a terminal part including a terminal fitting and a housing; and a first end part and a second end part configured to be arranged on the substrate in an arrangement direction. The terminal part includes a first locking portion provided in the housing and configured to be locked to adjacent parts on both sides in the arrangement direction. Each of the first end part and the second end part includes: a fixing portion configured to be fixed to the substrate; and a second locking portion configured to be locked to the first locking portion of an adjacent terminal part in the arrangement direction. The first end part, the terminal part, and the second end part are connected while being arranged in this order on the substrate.

An electrical circuit board plug contact device includes an electrical circuit board contact element and an electrical plug contact element formed separately from the electrical circuit board contact element. The electrical plug contact element is laterally offset with respect to the electrical circuit board contact element and an electrically conductive connection is provided between the electrical circuit board contact element and the electrical plug contact element.