The ball socket assembly includes a housing with an open interior which extends along an axis. A bearing is disposed in the open interior of the housing and has a curved primary contact surface which surrounds the axis and surrounds a stud ball opening. A stud ball is disposed in the opening and is in sliding contact with the primary contact surface for allowing rotation of the stud ball relative to the bearing. The stud ball has an equator and is in sliding contact with the bearing on both sides of the equator. A stud is operably connected with the stud ball. A shoe is further provided and has a pair of supplemental contact surfaces that are biased against the stud ball. The shoe provides the stud with a predetermined rotational torque and also adjusts for wear in the assembly to maintain the performance of the socket assembly.

A fastening system has a fastening element and at least one fastening device having a flanged housing, a closure element, a hollow-sphere element and a spherical insert. The hollow-sphere element pivots about a first pivoting axis relative to the flanged housing, while the spherical insert pivots about a second pivoting axis in the hollow-sphere element. First engagement means in an opening of the spherical insert are of complementary design to second engagement means of the fastening element. The first and second engagement means are designed such that, in a first rotational position, the fastening element can be inserted freely into the opening and, in a second rotational position, the first and second engagement means engage in one another.

A lamellar cover for use with an articulating joint is disclosed. The cover includes an annular retainer positionable adjacent a first portion of the articulating joint. A retainer fitting is positionable adjacent a second portion of the articulating joint that is moveable with respect to the first portion. A plurality of overlapping lamellar rings are supported between the annular retainer and the retainer fitting. Each lamellar ring includes a circular support ring, such as an o-ring, and a plurality of lamellas coupled to the circular support ring. One or more connectors extend between adjacent lamellar rings. Each of the plurality of overlapping lamellar rings has a ring diameter. One or more of the ring diameters decrease in size with respect to each other from the annular retainer to the retainer fitting thereby forming a tapered cover around the articulating joint.

A joint assembly of an adapter defines a first longitudinal axis and includes first and second hinges, first and second rings, a joint cover, and a biasing mechanism. The joint cover has first and second cover portions. The first ring is pivotally coupled to the first hinge and the first cover portion is pivotally coupled to the first hinge to define a first joint center. The second ring is pivotally coupled to the second cover portion and the second hinge is pivotally coupled to the second ring to define a second joint center that is spaced from the first joint center. The first and second joint centers define a cover axis of the joint cover. The biasing mechanism is engaged with the first ring and the joint cover to bias the joint cover towards an aligned configuration in which the cover axis is aligned with the first longitudinal axis.

The ball socket assembly includes a housing that is made as a monolithic piece and has an inner bore. The ball socket assembly also includes a ball stud that has a semi-spherically curved portion, a cylindrical portion, and a shank portion. The ball socket assembly further includes a backing bearing and an exit bearing. A third bearing is received on the cylindrical portion of the ball stud. The third bearing has a curved outer surface which cooperates with the curved inner surface of at least one of the exit and backing bearings for allowing the ball stud and the bearing to articulate and rotate relative to the housing. The third bearing is also in slidable contact with the cylindrical portion of the ball stud for allowing the ball stud to more freely rotate relative to the housing about the central axis.

The present invention relates to a stabilizer link for automobile suspensions, comprising: a tubular body (1), having at one end a pair of first flattened areas (2, 2) configuring a leak-tight closure of a first inner cavity (9) of the tubular body (1) located between both flattened areas (2, 2); and a first covering (4) made of polymeric material coupled, during the forming process thereof, on the end of the tubular body (1) such that it surrounds the pair of first flattened areas (2, 2), and wherein said covering (4) comprises a first articulation (6).

The present invention comprises a flexible coupling device, system and method for transferring high torque loads and complex rotary motion between components or devices. Specifically, high torque loads and complex rotary motions are transmitted from a motor, through and to an input shaft and to an output shaft, by way of a polygonal-shaped, flexible coupling, wherein one component or device may be misaligned with the input shaft. The flexible coupling consists of a reciprocating polygonal ball and socket design exhibiting a spherical, convex cap component made to provide variations and adjustments in alignment though a pivot point where rectangular, flat wear plates are utilized to evenly distribute received weight and elastomeric seals about the neck of the polygonal ball seal functionally sensitive components within a lubricating chamber.

A joint assembly of an adapter defines a first longitudinal axis and includes first and second hinges, first and second rings, a joint cover, and a biasing mechanism. The joint cover has first and second cover portions. The first ring is pivotally coupled to the first hinge and the first cover portion is pivotally coupled to the first hinge to define a first joint center. The second ring is pivotally coupled to the second cover portion and the second hinge is pivotally coupled to the second ring to define a second joint center that is spaced from the first joint center. The first and second joint centers define a cover axis of the joint cover. The biasing mechanism is engaged with the first ring and the joint cover to bias the joint cover towards an aligned configuration in which the cover axis is aligned with the first longitudinal axis.

A cannula lock for holding a medical device static in a select orientation relative to tissue. The cannula lock includes a shell with anchors. The anchors are deployed to the hold the shell static to the tissue. A pivoting brake (95) is disposed in the shell. The brake holds the medical device. When the orientation of the brake, by extension, the orientation of the device is established, the brake is set. The brake is set by expanding the brake (95) outwardly against the inner surfaces of the shell so as to hold the brake and medical device in the select orientation.

A rotary joint includes an inner joint element which has a spherically shaped inner convex joint face and an inner joint connection head protruding from the inner convex joint face; an outer joint element which has a spherically shaped inner concave joint face, a spherically shaped outer convex joint face and an outer joint connection head protruding from the outer convex joint face, wherein the inner joint element is held within the outer joint element such that the two joint elements can be rotated with respect to one another along the inner joint faces; and a joint bearing which has a spherically shaped outer concave joint face, wherein the outer joint element is held within the joint bearing such that the outer joint element can be rotated in the joint bearing along the outer joint faces.