The present invention provides a steering system for an in-wheel motor vehicle capable of controlling driving torques and speeds of in-wheel motors mounted in left and right wheels to be different from each other at the time of curve driving of the vehicle to generate a steering angle of the wheel for the curve driving, and performing a steering angle control of sensing the generated steering angle and fixing the steering angle to a desired steering angle.

A front wheel hub assembly disconnection arrangement configured to promote disconnection and outwards movement of a front wheel hub assembly from a vehicle body structure during a small partial overlap collision, including: a steering knuckle breaker and the front wheel hub assembly including a wheel hub and a steering knuckle for connection to a tie rod of a steering mechanism, the steering knuckle arranged on a rearward facing portion of the wheel hub, wherein the steering knuckle breaker is arranged on an A-pillar of the vehicle body structure and includes an impact surface facing the steering knuckle when the wheel hub is in a neutral position, such that in the event of a small overlap collision, the steering knuckle is displaced towards and collides with the steering knuckle breaker, such that the steering knuckle breaker breaks the steering knuckle and disconnects the steering knuckle from the wheel hub.

An automobile undercarriage component has at least three elongated arms, each including a web and a rib having an inner wall surface. One of the three elongated arms is a first arm having a first one of the ribs and at least one of the three elongated arms is a second arm having a second one of the ribs. For each of the second ones of the ribs, the leading end of the respective second one of the ribs has a width in the direction parallel to the plane of the web and transverse to the direction of elongation of the arm which is narrower than the width of a leading end of the first one of the ribs, as an inner wall surface is disposed closer to an opposing outer wall surface in the respective second one of the ribs as compared to the first one of the ribs.

A suspension device for vehicles (a front suspension (10)) is disclosed in which, of connecting portions (23, 24) of a lower arm (20) and a tie rod (6) for connection to a knuckle (35), one of the connecting portions (24) which is close to the rear of the vehicle is offset inward in the vehicle width direction with respect to the other connecting portion (23) which is close to the front of the vehicle, in the steering neutral state. The center (P2) of a lower end portion of a coil spring (60) is offset outward in the vehicle width direction and rearward in the vehicle's longitudinal direction with respect to the center (P1) of an upper end portion of the coil spring (60).

A vehicle strut assembly includes a boot and a coil spring. The boot has a vertical wall, a spring receiving portion and a centering portion projecting from the vertical wall. The coil spring has an end section, a transition section and a main section, the end section being fitted to the spring receiving portion encircling at least a portion of the vertical wall and defining a first radially inner diameter. The transition section has an increasing inner diameter extending from the end section to the main section. The main section defines a second radially inner diameter greater than the first radially inner diameter. The centering portion is positioned to contact a radially inner surface of the transition section of the coil spring restricting movement of the end section of the coil spring relative to the spring receiving portion of the boot.

A wheel suspension (1) for a motor vehicle, having a wheel carrier (3) which is mounted so that the wheel carrier (3) can pivot relative to a wheel-guiding control arm (4). The wheel-guiding control arm (4) includes a longitudinal control arm section (4a) with a forward body-side bearing (11) and a transverse control arm section (4b) with a rear body-side bearing (12). The rear body-side bearing (12) is designed as a ball joint.

The present invention provides a steering system for an in-wheel motor vehicle capable of controlling driving torques and speeds of in-wheel motors mounted in left and right wheels to be different from each other at the time of curve driving of the vehicle to generate a steering angle of the wheel for the curve driving, and performing a steering angle control of sensing the generated steering angle and fixing the steering angle to a desired steering angle.

An arrangement for attaching a control arm in a vehicle comprising a first attachment bracket, a first fastening means, a first bushing, and a control arm. The first bushing is arranged in an opening of the control arm and the first fastening means is passing through both the first attachment portion and the first bushing. The first attachment bracket comprises a slit arranged transversal to the travel direction of the vehicle and the slit is arranged in a front surface of the first attachment bracket, wherein the first attachment bracket is adapted to release the first fastening means of said control arm when a certain force is exceeded during an offset or small offset impact.

A wheel suspension for a vehicle including a carrier having a rotatably mounted bearing element. A spring damper strut connects to the carrier and the vehicle structure. A transverse control arm connects to the carrier at one end and at the other end to the vehicle structure. A control member connects to the carrier and the transverse control arm. The control member arranged relative to the transverse control arm such that a force application line of the control member is inclined toward a transverse control arm axis defined by a point of articulation of the transverse control arm on the structure side and a point of articulation of the transverse control arm on the carrier side wherein the force application line and the transverse control arm axis intersect between the points of articulation of the transverse control arm on the structure side and the carrier side.

A compact vehicle suspension system comprises a sliding ride motion guide having a fixed guide portion and a telescoping guide portion telescopically movable relative to one another. The sliding ride motion guide is fixed to a wheel hub knuckle via the fixed guide portion and is rotatably and structurally fixed via the telescoping guide portion at a top mount to a vehicle body. A coil over shock absorber is rotatably connected to a lower control arm at a first end and to the vehicle body at a second end. Arms of the fixed guide portion of the sliding ride motion guide may span the wheel hub knuckle to which a drive shaft may be connected. Vertical motion of the wheel is defined by a sliding axis of the sliding ride motion guide and an arc of the lower control arm.