A mechanical component for a vehicle, having a measurement region with a surface, and a force sensor is associated with the measurement region for detecting a force to which the component is exposed. The force sensor includes a layer of carbon nanotubes applied to the surface of the measurement region.

Provided is a technique whereby a DLC film having a desired surface roughness and a desired film hardness can be easily formed within a short period of time while preventing cost increase so that a large quantity of boll joints, which are less expensive and yet have stable sliding characteristics, can be supplied. A method for manufacturing a ball joint provided with a ball stud that has a spherical surface section and a holder section that pivotally holds the spherical surface section, said method comprising: an intermediate underlayer-forming step for forming an intermediate underlayer, that has a fine irregular surface structure, on the surface of the spherical surface section using a sputtering method; and an amorphous hard carbon film-forming step for forming an amorphous hard carbon film, that has a root mean square roughness on the surface of 6.5-35 nm, on the intermediate underlayer using a PIG plasma film formation method.

The present application discloses a ball joint that consists of a ball that may expand or contract, and a coupling that may expand or contract in order to lock the ball joint and prevent rotational movement. In the basic structure, the ball and the coupling may have an internal passageway that allows for a pressurized or depressurized member to pass through. The ball joint allows for a fixed condition that resists rotation under one pressure condition, and various degrees of rotation under a different pressure condition.

An apparatus is described for interconnecting a steering knuckle and lower suspension arm. The apparatus includes a ball joint assembly having a height adjustment feature and a non-concentric ball and shaft that together allow for increased range of camber adjustment.

A joint device (1), which has a second joint body (3), which second joint body is pivotably mounted in a ball socket (9) of a first joint body (12) by means of a joint ball (8). The joint ball (8) is a hollow ball and has, on its inner peripheral surface (23), output teeth (33), with which, in the ball interior (25), the input gears (55, 56) of two drive units (4, 5) rotatably mounted on the first joint body (2) are in tooth engagement. By selective rotation of one or both drive units (4, 5), the second joint body (3) can be driven to perform a working pivoting movement (6) relative to the first joint body (2).

Methods and system are provided for a steering pin and knuckle assembly. In one example, the assembly comprises a steering knuckle comprising a recess and a female threaded portion, a steering pin partially received in the recess, a connection member comprising a male threaded portion, and the male threaded portion of the connection member is engaged with the female threaded portion of the steering knuckle and the connection member fixes the steering pin on the steering knuckle.

A mounting pin assembly includes a first mounting component. The assembly also includes a second mounting component having a first leg located on a first side of the first mounting component and a second leg located on a second side of the first mounting component. The assembly further includes a mount pin extending through an aperture of the first leg, an aperture of the first mounting component, and an aperture of the second leg, the mount pin having a conical shoulder region in contact with a chamfer of the second leg. The assembly yet further includes a self-locking nut plate threaded to the mount pin.

The present disclosure relates to a shaft adapted to be at least partially inserted into an opening of a shaft receiver. The shaft comprises a nominal shaft portion adapted to be at least partially inserted into the opening of the shaft receiver, followed by an intermediate shaft portion that in turn is followed by a guide shaft portion terminating the shaft. The shaft comprises a cross-section with a cross-sectional contour in a plane including the central axis, the cross-sectional contour comprising a nominal shaft portion contour of the nominal shaft portion, an intermediate shaft portion contour of the intermediate shaft portion and a guide shaft portion contour of the guide shaft portion. The cross-sectional contour comprises a radial direction being perpendicular to the central axis, wherein, as seen in the radial directio, the nominal shaft portion contour is located at a nominal radial distance from the central axis.

An articulated stand including a first part and a second part. The first part is configured for holding an electronic device. The first part includes a ball pivot with a chamber and a connector. The chamber defined through the ball pivot. The connector accommodated at least partially in the chamber. The connector configured to electrically connect with a cable connector. The second part including a ball housing portion receiving the ball pivot to form a ball joint.

A ball joint and a dust cover in which a stable sealing function can be provided even when a space for disposing the dust cover is small are provided. The dust cover includes a deformable body portion, a fixed portion which is provided on one end side of the body portion and is fixed to a socket, and a seal portion provided on the other end side of the body portion. The seal portion has a main seal part which is provided to be slidable relative to a spherical portion side flange and an opposite side flange while sandwiched therebetween. The maximum length of the main seal part in a central axis direction in a state in which no external force is applied thereto is longer than a distance between opposing surfaces of the spherical portion side flange and the opposite side flange, where the central axis direction is a direction in which a central axis of the dust cover extends in a state in which no external force is applied thereto.