A rear wheel steering motor generates rotational force. A movement converter has a converting portion coupled to the wheel steering motor and configured to convert the rotational force transmitted from the rear wheel steering motor into a linear movement. An MR fluid is applied on the converting portion. An inverter controls driving of the rear wheel steering motor. A magnet switch works in concert with the inverter to change a magnetic field to selectively provide the magnetic field to the MR fluid of the movement converter.

The present embodiments provide a steering apparatus including a sliding shaft that is built into a shaft housing and linearly moves in the axial direction, a shaft coupling member coupled to an outer circumferential surface of the sliding shaft and axially sliding together with the sliding shaft inside the shaft housing, a magnet coupling member having a built-in magnet inside, coupled to the shaft coupling member, and axially sliding together with the sliding shaft inside the shaft housing, a sliding support member fixed to the shaft housing and slidably coupled to the magnet coupling member at a lower end thereof, and a sensor member coupled to the sliding support member and to which a sensor for detecting a magnetic field change of the magnet and a circuit board are mounted.

Methods, apparatus, systems and articles of manufacture are disclosed to perform a tank turn. An example vehicle includes a first wheel and a second wheel, the first wheel located on an end of a first axle, the second wheel located on an end of a second axle, the end of the first axle opposite to the end of the second axle, a first suspension coupled to the first wheel, a second suspension coupled to the second wheel, and a controller to drive the first axle in a first direction, drive the second axle in a second direction, the first direction different from the second direction, and decrease a first suspension load of the first suspension and a second suspension load of the second suspension.

A linear actuator for a steer-by-wire system including a component, in particular an axle or a shaft, that can be moved along a linear trajectory, and including a measuring device for determining a position of the component. The measuring device has a coil for inductively determining the position of the component, and the coil is arranged coaxially relative to the linear trajectory of the component.

A corner module apparatus for a vehicle may include a driver configured to provide a driving force to a wheel of a vehicle, a suspension connected to the driver, and being configured to absorb shock transferred from a road surface, and a steering unit connected to the suspension, the steering unit rotatably installed under a frame module coupled to a vehicle body, and being configured to adjust a steering angle of the wheel.

An embodiment independent corner module includes a knuckle fastened to a wheel, a steering frame fastened to the knuckle, the steering frame having an upper end configured to be fixed to a vehicle body and to rotate together with the knuckle to apply a steering angle to the wheel, a steering drive unit fastened to the steering frame, and a body guide rail fastened to the steering drive unit and configured to be disposed on the vehicle body, wherein, in response to reception of a driving force of the steering drive unit, the steering drive unit is configured to be rotated along the body guide rail and the steering frame is configured to be rotated simultaneously along with the rotation of the steering drive unit.

A steering control device has an electromagnetic clutch built into an electric motor. The electromagnetic clutch is provided with: an armature connected to a first closing member via a guide member, a coil holding part, and a bolt; a clutch plate connected to a rotor via a clutch plate attachment member, a key, and a motor shaft; and an excitation coil held by the coil holding part. The armature is fastened with the clutch plate when not attracted to the excitation coil during a power supply failure of the electric motor, and regulates relative rotation of the rotor with respect to a motor housing. Steering of a rack bar is thereby restricted at an optional steering position via the motor shaft, a worm shaft, and a steering shaft.

A dual-mode active rear-wheel steering device based on a multi-linkage mechanism, including: a steering angle control motor with a speed-reduction mechanism, a multi-linkage mechanism assembly for converting rotational motion of the steering angle control motor into linear motion of an end of the push rod, a steering actuating mechanism for converting linear motion of the multi-linkage mechanism assembly into rotation of a knuckle around a kingpin to make the rear wheels steer, a first electromagnetic pin puller and a second electromagnetic pin puller respectively configured to control a first extendable-retractable push rod assembly and a second extendable-retractable push rod assembly to work at a fixed or variable axial length. The device uses the steering angle control motor to drive the two rear wheels to turn in the same direction or opposite directions through the control of energized state of the two electromagnetic pin pullers.

Methods, apparatus, systems and articles of manufacture are disclosed to perform a tank turn. An example apparatus includes programmable circuitry to determine that a first brake associated with a first wheel is engaged and a second brake associated with a second wheel is engaged, the first wheel located on an end of a first axle of a vehicle, the second wheel located on an end of a second axle of the vehicle, the end of the first axle opposite to the end of the second axle, cause a first suspension to decrease a first suspension load of the first wheel, cause a second suspension to decrease a second suspension load of the second wheel, cause a first motor to drive the first axle in a first direction, and cause a second motor to drive the second axle in a second direction, the second direction different from the first direction.

Steering boxes currently available on the market in order to convert the rotation of the steering wheel into the angular rotation of the wheels are not suitable to be partially built into the rim of the wheels of an electric car. In addition, existing boxes do not allow the independent rotation of the wheels or wide turning radii. These limitations are overcome using a system comprising: a body into which at least one motor is built using corresponding supports, which motor(s) actuate(s) the steering rotation axle of each steered wheel in the upper part of the body, and, in the lower part, a transmission gearbox and a stationary circular crown gear with which driving pinions mesh, said pinions rotating about the crown gear, thereby rotating the entire body and the rotation axle of the wheel built into the body together with suitable means.