The connector shroud of the present invention includes an inner housing, a cam, a coupling nut and a lock nut. The inner housing has a grooved control link formed on an outer surface. The grooved control link extends in a longitudinal direction. The cam is disposed on the inner housing and is rotatable on the inner housing. The coupling nut is sleeved onto the inner housing. The coupling nut is configured to be coupled to an object. The coupling nut includes a tab extending from a rear end. The tab has a control slot formed thereon. The control slot extends in a direction not parallel to the longitudinal direction. The lock nut is sleeved onto the inner housing and includes a first pin and a second pin formed on an inner surface. The first pin is movable in the grooved control link and the second pin is movable in the control slot. When the second pin is in the control slot, a movement of the lock nut causes the coupling nut to rotate. When the first pin moves in the grooved control link in the longitudinal direction, the lock nut contacts the cam to make the cam rotate. The rotating cam applies a force perpendicular to the longitudinal direction to the tab to rotate the coupling nut.

The present invention provides a lever-type connector capable of preventing the position of a slider from being displaced by a gear of a wire cover coming into contact with rack teeth of a slider when the wire cover is attached to a housing. A lever-type connector (C) is provided with: a housing (10); a slider (20) that is provided to be movable in a first direction with respect to the housing (10), and has a plurality of rack teeth (22) arranged in the first direction; a wire cover (30) that is installed on the housing (10), and covers a wire draw-out surface (12) of the housing (10); and a lever (40) that is rotatably installed in the wire cover (30), has a gear (44) engaging with the rack teeth (22), and moves the slider (20). The housing (10) has a fulcrum part (50) that rotatably supports the wire cover (30), and a positioning part (60) that causes the gear (44) to face a position where the gear is engabeable with the rack teeth (22) by hitting against the wire cover (30).

A high temperature electrical connector, which may be used to connect a temperature sensor mounted in a combustion chamber of an automotive engine to a cable. The connector has a housing made of high temperature material, such as alumina ceramic. Connector terminals may be retained within the housing but may float relative to the housing, to reduce stresses associated with differential thermal expansion of the housing and terminals and reduce transmission of vibration and resultant degradation of connector performance. Compliant portions may extend from an intermediate portion of the terminals to make contact with pads on a sensor substrate inserted into the connector. The terminals may be retained with an end cap, secured to the housing. Retention of the terminals may be aided by pockets in the housing that receive tips of the terminals. Channels, receiving the intermediate portions of the terminals, may open into the pockets.

An electrical connection mount extending along an axial direction and comprising a movable element that can move along the axial direction between a contact position and an insulated position, wherein the movable element is configured to come into contact with at least one complementary contact of a complementary electrical connection mount in the contact position while the movable element is configured to be remote from the at least one complementary contact of the complementary electrical connection mount in the insulated position, the electrical connection mount comprising a displacement mechanism configured to move the movable element between the contact position and the insulated position when the electrical connection mount and the complementary electrical connection mount are engaged with each other and rotated relative to each other around the axial direction.

A connector assembly includes a first housing having an indicium imprinted thereon and a movable member movable from a first position configured to render the indicium illegible to an optical scanning device to a second position configured to render the indicium legible to the optical scanning device. The indicium is visible when the movable member is in the first position and when the movable member is in the second position. A method of mating a connector assembly having a movable member and an indicum imprinted thereon is also presented.

A connector is provided with a first housing (10), a second housing (20) connectable to the first housing (10), a guide functional unit (45) for enabling the first and second housings (10, 20) to approach/separate from each other in a relatively unrotatable state, a rotary member (30) for surrounding the first and second housings (10, 20), the rotary member being rotatable about an axis parallel to a connecting direction of the first and second housings (10, 20), and a cam functional unit (46) for causing the first and second housings (10, 20) to approach each other as the rotary member (30) is relatively rotated with respect to the first and second housings (10, 20).

A cam-lock fastening system is designed to accommodate a tolerance stackup to fasten a pair of rigid structures. A spring allows some longitudinal motion of the pin that would not be accommodated by the rigid structures or metal cam-lock and pin. The spring-loaded pin is also suitably designed to produce a preloaded structural joint that is between specified minimum and maximum loads for any tolerance stackup that is within specification. The fastening of the structures requires no manual adjustment of the pin, and facilitates blind connection of a high-fidelity electrical connector. Further, the described cam-lock fastening system is designed for high performance applications requiring preload forces in the thousands of pounds per square inch.

A connector having a housing, a slide member, and an operation lever. The slide member slides in response to operation of the operation lever. The slide member has a guide projection and slides while the guide projection is guided in a guide groove of the housing. The slide member has a cam groove that receives a cam pin in a second connector and the slide member, by sliding, performs mating with the second connector. The slide member has a first nipping portion that nips the cam pin when it slides to a completely mated position. The housing has a second nipping portion that nips the guide projection of the slide member when the slide member slides to the completely mated position.

An operating member (11) is displaceable to an assembled position, an initial position and a connection position with respect to a housing (10). The operating member (11) is rotated from the assembled position to the initial position with support shafts (18) inserted into end portions (41) of long grooves (39) serving as a center of rotation and includes a rotating mechanism configured to increase a laterally projecting amount of the housing (10) as the operating member moves from the assembled position toward the initial position and a sliding mechanism configured to move the operating member in a direction to reduce the laterally projecting amount from the initial position to the connection position while the support shafts (18) are displaced relative to the long grooves (39) and proceed with a connecting operation of the both housings (10, 12) by cam engagement with a mating housing (12) during a movement.

Disclosed is a socket apparatus for gripping the balls of a ball grid array (BGA), including a base member of electrically insulative material, an array of pairs of electrical contacts disposed in the base member in a configuration corresponding to a terminal ball configuration of said BGA to be mated with the socket apparatus, a first plate member disposed for slidable movement on said base member and having a plurality of parallel extension members extending therefrom and configured to pass through the array of pairs of electrical contacts, a second plate member disposed for slidable movement on said base member and having a plurality of parallel extension members extending therefrom and configured to pass through the array of pairs of electrical contacts, the plurality of parallel extension members of said first plate member disposed between the plurality of parallel extension members of said second plate member, a plurality of insulative nodules disposed on each extension member with nodules forming an array corresponding to said array of pairs of electrical contacts, and the first plate member and second plate member being movable relative to each other on said base member whereby the plurality of insulative nodules urge the corresponding electrical contacts into electrical contact engagement with the balls of a BGA in the socket.