A method of modeling layout of rigid tubing comprises securing a first component of a lockable adjustment assembly to an end A of a first rigid tube via a first releasable coupling assembly. The method also comprises securing a second component of the lockable adjustment assembly to an end C of a second rigid tube via a second releasable coupling assembly. Further, the method comprises moving the first component and the second component, loosely coupled with each other, relative to each other with only three degrees of freedom to position the first rigid tube and the second rigid tube in a selected orientation with respect to each other. The method also comprises, with the first rigid tube and the second rigid tube in the selected orientation relative to each other, locking the lockable adjustment assembly so that the first component and the second component have zero degrees of freedom relative to each other.

The socket assembly includes a housing that presents an inner wall which surrounds an open bore. A stud is partially received in the open bore with a bearing interposed between the inner wall and the stud. The bearing has a bearing piece, which is in surface-to-surface contact with the stud, and a preload piece which is elastically compressed to impart a biasing force on the bearing piece, thereby preloading the bearing piece against the stud. The preload piece is in an overmolded engagement with the bearing piece to securely couple these pieces together such that the bearing can be inserted into the open bore of the housing together as a unit. The bearing and preload pieces are made of different materials with different elasticities.

A ball joint orientation device applicable to a unipod includes a ball joint and stop members, in which one end of the ball joint is formed as a rotating part and is arranged in a ball joint seat in a universal swaying manner, and the other end extends to form a connecting part and is fixedly connected with a main rod; the stop members are arranged in the ball joint seat, and include a locking stop member located at the upper side of the rotating part; an orientation knob is sleeved on the connecting part and/or the main rod; when screwed toward the direction close to the ball joint seat, the ball joint is subjected to orienting locking and no longer rotates; and when screwed toward the direction away from the ball joint seat, and the orienting locking is released, so the ball joint is rotatable freely.

A method comprises securing a first component of a lockable adjustment assembly to an end A of a first rigid tube via a first releasable coupling assembly. The method also comprises securing a second component of the lockable adjustment assembly to an end C of a second rigid tube via a second releasable coupling assembly. Further, the method comprises moving the first component and the second component, loosely coupled with each other, relative to each other with only three degrees of freedom to position the first rigid tube and the second rigid tube in a selected orientation with respect to each other. The method also comprises, with the first rigid tube and the second rigid tube in the selected orientation relative to each other, locking the lockable adjustment assembly so that the first component and the second component have zero degrees of freedom relative to each other.

A modeling assembly (100) for layout of rigid tubing comprises a first releasable coupling assembly (110) and a second releasable coupling assembly (120). The modeling assembly (100) also comprises a lockable adjustment assembly (130) comprising a first component (140) and a second component (150). The first component (140) is configured to be removably coupled to an end A of a first rigid tube (102) via the first releasable coupling assembly (110). The second component (150) is configured to be removably coupled to an end C of a second rigid tube (104) via the second releasable coupling assembly (120). With the lockable adjustment assembly (130) in the loose coupled state, the first component (140) and the second component (150) have only three degrees of freedom relative to each other. With the lockable adjustment assembly (130) in the locked coupled state, the first component (140) and the second component (150) have zero degrees of freedom relative to each other.

The socket assembly includes a housing that presents an inner wall which surrounds an open bore. A stud is partially received in the open bore with a bearing interposed between the inner wall and the stud. The bearing has a bearing piece, which is in surface-to-surface contact with the stud, and a preload piece which is elastically compressed to impart a biasing force on the bearing piece, thereby preloading the bearing piece against the stud. The preload piece is in an overmolded engagement with the bearing piece to securely couple these pieces together such that the bearing can be inserted into the open bore of the housing together as a unit. The bearing and preload pieces are made of different materials with different elasticities.

A modeling assembly (100) for layout of rigid tubing comprises a first releasable coupling assembly (110) and a second releasable coupling assembly (120). The modeling assembly (100) also comprises a lockable adjustment assembly (130) comprising a first component (140) and a second component (150). The first component (140) is configured to be removably coupled to an end A of a first rigid tube (102) via the first releasable coupling assembly (110). The second component (150) is configured to he removably coupled to an end C of a second rigid tube (104) via the second releasable coupling assembly (120). With the lockable adjustment assembly (130) in the loose coupled state, the first component (140) and the second component (150) have only three degrees of freedom relative to each other. With the lockable adjustment assembly (130) in the locked coupled state, the first component (140) and the second component (150) have zero degrees of freedom relative to each other.