A link and ball socket assembly for a vehicle position sensor comprising a first molded member including a link and a first socket and a second molded member including a second socket coupled to the first molded member. The first socket is molded to and integral with a first end of the link and the second socket is coupled to and rotatable relative to a second opposed end of the link. The first socket defines an interior ball receiving pocket. The interior pocket defines a first back pocket portion which opens into a second front ball shaped pocket portion. The ball is received in the first back pocket portion and slid and snapped into the second front pocket portion. A locking pin is inserted into the interior pocket into a relationship abutting against the ball for retaining the ball in the socket.

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 joint for a vehicle, the joint having an outer sleeve, a joint shell for receiving a movably supported joint inner portion, and an inner sleeve, at least part of which is arranged between the joint shell and the outer sleeve. The inner sleeve has two radially outwardly projecting rim cylinders which are axially mutually spaced and run around the outer periphery of the inner sleeve, and the two rim cylinders define a peripheral recess on the outer periphery of the inner sleeve. The joint is characterized in that a press-fit device designed integrally with the inner sleeve extends in the region of at least one rim cylinder of the inner sleeve radially outwards beyond the outer diameter of the rim cylinder.

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 universal joint includes a driving portion and a joint head. The driving portion includes a ball nest and a polygonal column disposed within the ball nest. The joint head includes a working end portion and a ball head portion, and the ball head portion is rotatably and swingably disposed within the ball nest. A shaped of the ball head portion corresponds to a shaped of the ball nest, and the polygonal column is co-rotatable with the ball head portion. The ball head portion including a polygonal groove, and the polygonal column is inserted within the polygonal groove.

A fan mount includes a first part movable relative to a second part. A retainer is connected to the second part of the fan mount above the first part for restricting the movement of the fan relative to the fan mount. The first part may be a ball member having a depending portion with an hourglass shape. A safety connector may be provided, and a retainer connected to the second part of the fan mount for retaining the safety connector. A cover may also be provided for mounting to the second part, the cover including a central opening for receiving the support. A trim piece is adapted for telescoping within the opening of the cover.

One embodiment of an outrigger footpad retainer system is described and depicted. The system may include a spider assembly that has an upper unit and a lower unit. The upper unit may have a retainer portion and two legs extending from the portion. The lower unit may have a retainer portion and two legs extending from the portion. The upper portion may at least partially overlap the lower portion.

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 ball joint assembly for a vehicle includes a mounting part including an inner circumference part forming a hole in a vertical direction; a ball stud including a ball and a stud extending from the ball; a bearing coupled to surround the ball and disposed in the hole; and an insert molding part for filling the space of the hole formed between the inner circumference part and the outer surface of the bearing. The inner circumference part includes at least one upper protruding part protruding from an upper area thereof in a direction toward a central axis of the hole and at least one lower protruding part protruding from a lower area thereof in a direction toward the central axis.

A quick-disconnect ball and socket joint includes a substantially spherical strain relief node configured to be coupled to an object, such as a cable. The system further comprises an end cap configured to capture the substantially spherical strain relief node, the end cap having a diameter that permits the substantially spherical strain relief node to pass therethrough when the system is in an open position. The system still further comprises a retaining element configured to retain the substantially spherical strain relief node in the end cap. The retaining element is attached to the end cap when the system is in a closed position and the object is prevented from being removed from capture by the end cap. However, in the open position, the retaining element may be removed from capture by the end cap by passing the substantially spherical strain relief node through a diameter of the end cap.