An electrical data connector comprises a plug (2) that is configured for insertion in a longitudinal direction into a complementary receptacle (6). The plug (2) includes a connector element (10) that is configured to be received within the receptacle and carries a plurality of electrical connectors, a body (14) that is located externally of the receptacle when the connector element is inserted into the receptacle, and a releasable locking mechanism (22) for locking the plug positively to the receptacle to prevent unintentional removal of the plug from the receptacle. The locking mechanism includes a locking element (30) carried by the connector that is configured for movement between a locked configuration in which it protrudes from the connector element and an unlocked configuration in which it does not protrude substantially from the connector element, a locking control (20), provided on the body, for manually actuating the locking mechanism, and a drive mechanism that connects the locking control to the locking element, whereby operation of the locking control actuates the locking element. The drive mechanism includes at least one longitudinal sliding element (26) that is connected to the locking control and at least one transverse sliding element (28) that is connected to the locking element, wherein said longitudinal and transverse sliding elements are located in a common plane and are configured such that longitudinal movement of the longitudinal sliding element drives transverse movement of the transverse sliding element, thereby actuating the locking element.

A panel fuse module for use with one or more fuses. The panel fuse module includes a housing with a first fuse contact and a second fuse contact. The first fuse contact is resiliently deformable and is mounted on a post of the housing. A movable fuse holder is provided which is moveable relative to the housing and relative to the first fuse contact. A cam member is provided on the movable fuse holder. As the movable fuse holder is moved from the first position toward the second position, the cam member cooperates with the first fuse contact to move the first fuse contact from a less-stressed first position to a more-stressed second position to allow the respective fuse of the one or more fuses to be inserted into the housing without engaging the first fuse contact.

Provided is a connection structure for a power storage module in which a wiring module is mounted on a power storage element group including multiple power storage elements, and for a control device for detecting states of the electrical elements. The power storage module includes detection wires that detect the states of the power storage elements, and that are connected to the control device. A module-side connector that is connected to the detection wires and is integrally provided on the power storage module is fit onto the device-side connector that is integrally provided on the control device.

A securement device for engagement with a cable connector held in a mating socket by a release lever. The device features at least one socket formed into a body which is configured to engage with a cable connector which requires a release lever to maintain the cable connector in the socket. A locking pin engageable through opening on a sidewall is positionable to contact against a shoulder of the cable connector from which the release lever extends to hold the cable connector in the socket until the locking pin is removed. Defective cable connectors lacking an operative release lever can also be held in operative engagement in the socket by the locking pin.

An electronic device testing apparatus with a locking mechanism for locking a press head and a socket plate is provided. When an electronic device is to be tested, a lifting arm is lowered so that a contact portion is in contact with the electronic device, and a locking mechanism is actuated to detain the press head on the socket plate. A pressing force generating device exerts a pressing force onto the electronic device and the socket plate, and at least a portion of a reaction force can be directed back to the locking mechanism. The locking mechanism is adapted to detain the press head on the socket plate. When the pressing force generating device generates a predetermined pressing force to certainly establish electrical connection between the electronic device and the chip socket, the reaction force produced by the chip socket may be distributed over the locking mechanism.

Disclosed is a socket apparatus for ball grid array (BGA) balls, including a base member of electrically insulative material, a plurality of electrical contact members disposed in row and column configuration attached to the electrically insulative material, a plate member extending in a row direction, and a plurality of extension members connected to the plate member and configured to press BGA balls of a mounted BGA into the plurality of electrical contact members when the plate member is pulled in a first direction.

A communication system includes first and second circuit card assemblies mated such that first and second PCBs move relative to each other along a board mating axis parallel to a slot in the first PCB with the first PCB oriented perpendicular to the second PCB and with first and second mating ends of first and second electrical connectors oriented parallel to the board mating axis. The first and second circuit card assemblies are mated such that the first electrical connector and the second electrical connector move relative to each other along a connector mating axis perpendicular to the board mating axis. First mating interfaces of first contacts are mated to second mating interfaces of second contacts in a contact mating direction non-parallel to the board mating axis and non-parallel to the connector mating axis.

A connector includes a first-housing, a second-housing, a shroud, and a stacked-gear. The stacked-gear is moveably mounted to the first-housing. The stacked-gear engages a first-gear-rack on the second-housing and a second-gear-rack on the shroud. The second-housing is mated with the first-housing when the shroud is moved along a mating-axis of the connector. The stacked-gear engages at least two teeth on the first-gear-rack and on the second-gear-rack when the second-housing is mated with the first-housing. A rotation of the stacked-gear is greater than ninety degrees when the shroud is moved from an unmated-position to a mated-position. The stacked-gear initially engages a first-side of a first-tooth of the first-gear-rack when the first-housing receives the second-housing. A uniform mating-force is maintained as the shroud is moved from an unmated-position to a mated-position. A mechanical advantage to produce the mating-force is increased as the shroud is moved from an unmated-position to a mated-position.

A terminal block for an electronic device, which block can be attached to an electronics housing of the electronic device, includes at least one base strip comprising a plurality of connector sockets; and a plurality of connector modules that can be attached to the connector sockets of the at least one base strip in at least one insertion direction, are held on the connector sockets in an inserted position, and can be released from the connector sockets to be removed from the at least one base strip; and a locking device. The locking device includes: an actuating part that can be moved relative to the at least one base strip in an actuation direction; and a plurality of locking elements that are engaged in a locking manner in mating elements of the connector modules in a locked position.

An electrical connectors housing for receiving a pair of mated electrical connectors designed to provide easy connection and prevent inadvertent disconnection of electrical connectors, comprises a male electrical connector housing member; a female electrical connector housing member configured to receive the male electrical connector housing member; and cam-lock couplings to lock together female and male electrical connector housing members.