A steering system with an actuating device (1), in particular a rear axle steering system, having a spindle drive (3) with a spindle (5) and a spindle nut (4) which is fitted into the housing (2) of the steering system in a positionally fixed but rotatable manner and is driven by an electric motor (9). The electric motor (9) is a vernier motor that drives the spindle drive (3) and is integrated in the spindle drive (3). The actuating device (1) is used for a rear axle steering system of a motor vehicle.

Vehicle suspension systems are described herein. An example apparatus includes a cam pivotably coupled to a rear axle. The example apparatus also includes a first tie rod having a first end pivotably coupled to the cam and a second end pivotably coupled to a steering knuckle. The example apparatus also includes a second tie rod having a first end pivotably coupled to the cam outboard relative to the first end of the first tie rod and a second end coupled to a steering actuator.

A control apparatus for a rear wheel steering system is provided to control the rear wheel steering system by calculating a target rear wheel steering angle using sensors included in a parking assist system. The control apparatus includes a first sensor and a second sensor spaced apart from each other and mounted on a rear portion of a vehicle, a determiner configured to determine whether a trailer is mounted at a rear side of the vehicle using the first sensor or the second sensor, and a controller configured to control the rear wheel steering system according to a target rear wheel steering angle calculated using the first and second sensors when it is determined that the trailer is mounted at the rear side of the vehicle.

A toe angle control system for a vehicle, includes: an actuator having an output part configured to receive a driving force of an electric motor via a gear transmission mechanism and to be displaced by the driving force such that a displacement of the output part varies a toe angle of a wheel; and a controller controlling the electric motor, wherein the controller is configured to calculate an operation quantity of the electric motor, and, when the controller determines that a current displacement direction of the output part and a displacement direction of the output part corresponding to the operation quantity are opposite to each other, the controller corrects the operation quantity to reduce the operation quantity.

A suspension for a wheel of an axle of a motor vehicle, comprising a wheel support, which is mounted on the vehicle body via a plurality of links and which has a first supporting element and a second supporting element. A vehicle wheel is mounted rotatably on the first supporting element and the first supporting element is rotatable relative to the second supporting element for transmitting a steering torque by a steering actuator arranged on the wheel support. The first supporting element is attached to the vehicle body by an upper wishbone, and the second supporting element is attached to the vehicle body exclusively by a lower wishbone.

A dual-mode active rear-wheel steering device, including: a steering motor, a main shaft, an intermediate gear, a transmission gear, a planetary gear coupling mechanism and a mode switching assembly. An output end of the steering motor is provided with a first input gear. An end of the main shaft drives a first rear wheel to rotate by a two-stage gear transmission system and a first rear-wheel motion conversion mechanism, and the other end of the main shaft drives a second rear wheel to rotate by the planetary gear coupling mechanism and a second rear-wheel motion conversion mechanism. The intermediate gear, the transmission gear and a sun gear of the planetary gear coupling mechanism are provided on the main shaft. The intermediate gear meshes with the first input gear.

A vehicle steering system includes: actuators, respectively provided for wheels, for changing toe angles of the wheels; lock devices, respectively provided for the wheels, for restricting changes in the toe angles of the wheels; and a control device for controlling the actuators and the lock devices. For each lock device, the control device at a time performs an individual unlocking operation of unlocking the lock device, and a lock relaxation operation of relaxing a locked state of the lock device.

A lock mechanism is provided in an actuator capable of changing a toe angle of a wheel by rotational drive of a motor and adapted to lock operation of the actuator when the rotational drive of the motor is stopped. The lock mechanism includes a casing secured to a housing of the actuator, an input-side shaft connected to a motor shaft of the motor and rotatably held in the casing, an output-side shaft to which rotational torque is transmitted from the input-side shaft, and an engaging part. The engaging part includes a pair of friction members displaceably provided along a guide groove, a claw part having an acute shape in cross section and a side end part which are provided on the input-side shaft, an abutting part provided on each friction member, and a coil spring for urging each friction member.

A suspension and traction system is described for a vehicle equipped with a frame and a propulsive element (92) by rolling on the ground. An electric actuator (M3) is used for determining a steering angle () of the propulsive element.

The present invention provides a vehicle control device and method capable of ensuring steering accuracy. In a vehicle provided with a left-right pair of steered wheels for which the braking/driving forces can each be controlled, and a steering force generation device that generates steering force for the steered wheels and controls the steering angle of the steered wheels, this vehicle control device and method control the steering force and the steering reaction force from the steering force generation device by controlling the braking/driving force of each of the steered wheels on the basis of the lateral force acting on the steered wheels.