An axial ball joint is provided with: a ball stud including a stud section and a ball section; a metallic housing which rotatably supports the ball section of the ball stud; and a resin-made ball seat which is provided to be interposed between the ball section and the housing. The housing is formed into a bottomed cylinder shape by pressing. The thickness of a bottom wall and the thickness of a circumferential side wall of the housing are set to be equal to each other. A plurality of bead sections are formed on the inner bottom of the housing by press-molding or forging.

A floating joint includes a driving side coupling portion and a driven side coupling portion serving as first and second connections. A pressure adjusting structure in the floating joint is provided between the bottom surface exposed region of the spherical portion for contact and the bottom surface facing region of a fixing ring without a gap, and has elasticity. Therefore, the floating joint relatively firmly maintains the one-side spherical contact relationship, in which the top region of the spherical portion for contact contacts a part of the bottom surface portion of the frame body by the elastic force of the pressure adjusting structure.

A ball channel and ball channel assembly are disclosed with the ball channel having a channel top, a channel bottom, and an inner portion including a first inner sidewall, a second inner sidewall, a first end wall, and a second end wall. A first resilient tab extends from the first inner sidewall with a first tab end surface, and a second resilient tab extends from the second inner sidewall with a second tab end surface. An elongated gutter extends longitudinally along the inner portion and adjacent the channel bottom, wherein the combination of the first and second tab end surfaces and a gutter top surface form a ball track for receiving a head of a ball stud and allowing secured sliding longitudinal movement of the head. An outer portion is also provided having a flange wall that is configured to engage a receiving wall of a mounting panel.

The invention relates to a valve assembly (10) for a charging device, in particular for a wastegate of an exhaust gas turbocharger, comprising a spindle (100), a lever arm (110) coupled to the spindle (100), and a valve unit (200). The lever arm (110) has a connecting element (112), designed as at least partially spherical, and the valve unit (200) has an accommodation region (212) with at least one first conical accommodation surface (214) in which the connecting element (112) is arranged.

A ball and socket joint assembly is disclosed that includes a body defining a cavity, a collet disposed in the cavity to receive a ball of a connector, and an actuator shaft coupled to the collet for rotating and translating the collet in the cavity. The cavity has a distal opening to accept the ball and an engagement feature extending into the cavity. The collet has an outer diameter larger than the opening in the body when the ball is disposed in the collet, and the collet has a corresponding engagement feature around at least a portion of the outer surface for receiving the engagement feature and converting rotation of the compression member into translation of the compression member along a proximal-distal axis of the body. The collet is compressed against the opening of the cavity when the collet is advanced distally against the opening.

A work vehicle includes a chassis defining a longitudinal axis, a prime mover configured to move the chassis in the direction of the longitudinal axis, and a steering assembly configured to pivot a wheel relative to the chassis. The steering assembly includes a knuckle coupled to the wheel, a tie rod coupled to the knuckle and having a ball portion, a steering cylinder, and a joint assembly. The steering cylinder is slidably coupled to the chassis and configured to translate relative to the chassis along a cylinder axis perpendicular to the longitudinal axis. The steering cylinder includes a connection portion having an inner circumferential surface that partially defines a bearing pocket. The joint assembly couples the ball portion to the connection portion and includes a bearing race that is received into the bearing pocket in direct contact with the inner circumferential surface. The bearing race receives the ball portion.

A sealing element for a ball joint has a sealing area on the housing side and a sealing area a distance away therefrom in an axial direction of the sealing element on the stud side. Arranged between the housing-side sealing area and the stud-side sealing area is an outlet opening which extends through the sealing element to allow the passage of spent lubricant. The outlet opening extends in the axial direction of the sealing element, passing all the way through the sealing element in the axial direction. Further, the sealing element is incorporated in a ball joint which is incorporated in a two-point control arm.

Disclosed is a plug connector for contacting electrical lines. The plug connector has a first plug part and a second plug part. The first plug part and the second plug part are each designed for receiving and contacting of an electrical cable. The first plug part has a spherical shell as a contact region and the second plug part has a sphere as a contact region. By this geometric design, the first plug part and the second plug part can be variably aligned and fastened to each other. Particularly advantageously and flexible, the first plug part and the second plug part can be adjusted without the contact and connections having to be dismantled.

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 invention relates to a valve assembly (10) for a charging device, in particular for a wastegate of an exhaust gas turbocharger, comprising a spindle (100), a lever arm (110) coupled to the spindle (100), and a valve unit (200). The lever arm (110) has a connecting element (112), designed as at least partially spherical, and the valve unit (200) has an accommodation region (212) with at least one first conical accommodation surface (214) in which the connecting element (112) is arranged.