A rack bush of a steering device for a vehicle may include: a bush body part installed in a rack housing of the steering device for a vehicle so as to cover a rack bar, and configured to guide the rack bar to move in an axial direction; a first uneven part formed in an uneven shape on an outer circumferential surface of the bush body part, and configured to bring the bush body part and the rack housing into line contact with each other; and a position fixing part formed at one end of the bush body part, and configured to prevent the bush body part from moving in the axial direction.

An adjustment drive for a steering column may include a drive unit having a threaded spindle that is supported in a gearbox housing at a bearing portion so as to be rotatable, with the threaded spindle including a threaded portion with a spindle thread that is axially adjoined to a shaft portion on which a gear wheel is arranged in a rotationally secure manner. The gear wheel meshes with a drive wheel that is coupled to a motor. Between the threaded portion and the gear wheel a peripheral bearing groove with a groove base may extend between groove flanks thereof. The bearing portion may be disposed in the bearing groove in a region of the groove base, and the bearing portion may be supported in a sliding manner in a bearing opening of a bearing plate that engages radially in the bearing groove.

A joint fork (1) for connection to a joint. The joint fork having two side plates (2a, 3) that are arranged approximately parallel with one another, and each having a side plate surface (F1, F2). A web (2b) connects the side plates (2a, 3) with one another. A fixing bore (6) is arranged in the web (2b) and has a longitudinal axis (a). The joint forks (1) are coupled to an actuator. The side plate surfaces (F1, F2) form, with the longitudinal axis (a), an angle of inclination (α) and the angle of inclination (α) is in the range from 20° to 70°, in particular around 30°. The actuator is fitted with the joint forks (1).

Steering column for a motor vehicle including two telescopic drive shafts linked in rotation, allowing an axial sliding of a front shaft supporting a steering wheel, successively over, starting from the most forward position, a first range of depth adjustment of the position of this steering wheel, then a second damping range used in the case of an accident for damping an impact of the driver on the steering wheel, this column including an electric motorization for controlling the sliding, and an anti-theft blocking device blocking the rotation of one of the shafts, which is automatically engaged for an axial position for blocking the front shaft given by the motorization located in the second damping range.

A noise reduction apparatus for an electric power steering system may include a worm wheel rotatably and integrally coupled to a steering shaft connected to a steering wheel; a worm gear shaft to be rotatably operated by rotational force of an electric motor and formed with a worm gear to be meshed with the worm wheel; a tilt bearing provided between the worm gear shaft and the electric motor to rotatably support one end of the worm gear shaft; a support bearing for rotatably supporting the other end of the worm gear shaft; a plurality of pressing pins for pressing the support bearing; and a plurality of elastic members for elastically supporting the plurality of pressing pins respectively.

A modular chassis is provided for an off-road vehicle to improve assembly, servicing, and repairing of a drivetrain of the off-road vehicle. The modular chassis includes a chassis to support components of the off-road vehicle. A front frame module couples with a front of the chassis, and a rear frame module couples with a rear of the chassis. The front frame module supports lower suspension arms of the off-road vehicle by way of inboard bushing joints. The front frame module supports at least a steering gear and a front differential of the off-road vehicle. The rear frame module is a tube-frame structure that supports components of the off-road vehicle. A lower portion of the rear frame module extends rearward and acutely upward to a top frame member that couples with upper side portions of the chassis. Several cross-members impart structural integrity to the rear frame module.

A clearance is created between an inner circumference of a bushing main body (2) which surrounds a rack (5) across a row of rack gear teeth (50) and an outer circumference of the rack (5), and two supporting surfaces (21A, 21B) which face each other with a bushing main body axis O therebetween and a supporting surface (21C) which faces a back surface of the rack (5), each extending along an x-axis direction, are formed on the inner circumference of the bushing main body (2). The rack (5) in a neutral state is supported by the two supporting surfaces (21A, 21B) so as to be displaceable along a z-axis direction, and the rack (5) in operation is stably supported by the three supporting surfaces (21A-21C) at three places. A groove bottom position of an annular elastic member attachment groove (24), which is formed on an outer circumference of the bushing main body (2), is offset toward the support surface (21B) only in an area on a support surface (21B) side from the bushing main body axis O, and therefore an elastic ring (3) attached to the elastic member attachment groove (24), protrudes above an outer circumferential surface of the bushing main body (2), but only in the area on the support surface (21B) side from the bushing main body axis O.

A rack supporting device for vehicle steering systems includes: a steering housing having a steering gear installed therein; a rack bar longitudinally inserted into the steering housing to engage with the steering gear; a tapered passage defined in an inner circumference of the steering housing, wherein the tapered passage is eccentric with an axial center of the steering housing; a rack bushing inserted between an inner circumference of the tapered passage and an outer circumference of the rack bar so that the rack bushing moves along the tapered passage and pushes the rack bar to the steering gear; and an elastic member mounted to one side of the tapered passage to provide an elastic pressing force for pushing the rack bar to the rack bushing.

A steering shaft assembly comprising female shaft and a male shaft. The female shaft includes an inner surface defining a plurality of outer roller bearing tracks. The male shaft includes an outer surface defining a plurality of inner roller bearing tracks. An adaptable sleeve assembly is located between the inner surface of the female shaft and the outer surface of the male shaft and includes a body. The body defines an outer surface for contacting the inner surface of the female shaft and an inner surface for contacting the outer surface of the male shaft. The body defines at least one rib projecting radially outwardly from the outer surface of the body and projecting radially inwardly from the inner surface of the body. The at least one rib is inserted into one of the plurality of inner roller bearing tracks and one of the plurality of outer roller bearing tracks.

The disclosure relates to a mounting unit for mounting a steering shaft in an associated mounting sleeve, which unit comprises a mounting body, at least two first mounting arms and at least two second mounting arms for radially supporting the mounting unit within the mounting sleeve. A roller bearing is provided on a radially inner side of the mounting body, the mounting body forming an outer ring of the roller bearing on which rolling elements roll. In addition, the disclosure relates to a steering column assembly in which a steering shaft is mounted radially within a mounting sleeve by such a mounting unit.