A stabilizer link of the present invention includes connecting parts that has a housing which supports a ball stud to be connected to the first or second structure so as to be swingable and rotatable, wherein the ball stud has a stud part extending from a spherical part and the housing houses a support member to support a spherical part of the ball stud in a spherical space so as to be slidable, wherein the support member includes: an opening where the spherical space is open for the stud part; a lubricant receiving part in a concave shape that faces the opening; and a wall surface that forms the spherical space for the spherical part to slide thereon and has recessed grooves formed on both sides or one side of a portion of the wall surface having the maximum inner radius about the central axis of the spherical space.

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 socket assembly has a housing with an inner bore which extends from a first end to a second end. A ball portion of a ball stud is received in the inner bore. A backing bearing is disposed in the inner bore and presents a curved bearing surface in surface-to-surface contact with the ball portion. A first spring biases the backing bearing against the ball portion. The socket assembly also includes an exit bearing with a cylindrical portion that is in contact with an equator of the ball portion and a semi-spherical portion that is in surface-to-surface contact with an opposite hemisphere from the first bearing surface. A second spring biases the exit bearing into a predetermined location established by the housing. The exit bearing is movable from the predetermined location in a direction towards the second end of the housing against a biasing force of the second spring.

A joint ball device which is connected to a ball end of a control lever may be provided. The joint ball device includes: a ball seat which is formed to have a hollow cylindrical body and at least a pair of slots formed in a longitudinal direction of the body from an end of the body, and which includes a receiving portion defined by the body so as to receive the ball end of the control lever on the end of the body, and includes a stopper which protrudes from an outer circumferential surface of the body; and a cable end portion which is connected to a shift cable and is fastened to the ball seat. The stopper of the ball seat is fastened to the cable end portion.

The ball joint assembly includes a housing that has an inner wall which surrounds an open bore that extends along a central axis. The ball joint assembly further includes a ball stud with a ball portion that is received in the open bore of the housing and with a shank portion that projects out of the open bore through an open end of the housing. At least one bearing is also disposed in the open bore. The at least one bearing has a curved bearing surface which is in slidable contact with the ball portion of the ball stud for allowing the ball stud and the housing to rotate and articulate relative to one another. The bearing is made as a single, monolithic piece of nylon 4/6.

A ball joint holder with limiting element includes a lower base, an upper base covered to the lower base, a ball shaft and a limiting element. The ball shaft has a rotation rod, and a ball body located around a lower end of the rotation rod. A lower end of the rotation rod protrudes outward to form a limiting block. Two opposite ends of the limiting element are pivotally connected with the lower base and the upper base. The limiting element opens a limiting groove. One of inner surfaces of a front wall and a rear wall of the limiting groove is defined as a limiting surface. The lower end of the rotation rod and the limiting block are received in the limiting groove. The limiting block is capable of abutting against the limiting surface.

A multi-directional mounting bracket for adjustably mounting an object to a structure, such as a loudspeaker is disclosed. The mounting bracket incorporates a ball and socket mounting arrangement. Locking means including an array of indentations is provided, wherein the indentations define a plurality of predetermined positions.

A ball joint assembly includes a housing at least partially defining a cavity. A ball stud includes a head portion positioned within the cavity and a shaft extending from the head portion. A ball race having an inner surface is positioned within the cavity to define an interface between the inner surface of the ball race and an outer surface of the head portion. A solid friction coating is positioned within the interface. The solid friction coating is coupled to the inner surface of the ball race and/or the outer surface of the head portion of the ball stud. A piston can also be positioned within the cavity, wherein at least one gap is defined between the ball race and the piston and/or between the ball race and the housing. Methods of assembling a ball joint assembly are also disclosed.

A socket for a vehicle assembly is disclosed. The socket comprises a mounting structure comprising a plurality of side portions forming a first frame and a ball receiving structure formed by a second frame. The second frame is disposed within a perimeter of the first frame and comprises a plurality of support beams interconnected with the side portions of the first frame. The socket further comprises a ball mount interface comprising a contoured recess formed in each of the beams. The ball mount interface is configured to receive an exterior surface of a ball to form a ball and socket assembly.

A socket assembly includes a housing having an inner bore extending along a central axis between a closed first end and an open second end. At least one bearing is disposed in the inner bore, wherein the at least one bearing has a bearing surface and a support surface opposite the bearing surface. The socket assembly also includes a ball stud having a shank portion extending outwardly from the housing through the open second end and a ball portion disposed in the inner bore. At least one preload washer biases the at least one bearing into engagement with the ball portion of the ball stud. The at least one preload washer has an outer coating of a low friction, heat insulating material.