An active suspension system comprises at least one biasing device configured to support a body from a structure, and at least one motor. A magnetorheological (MR) fluid clutch apparatus(es) is coupled to the at least one motor to receive torque from the motor, the MR fluid clutch apparatus controllable to transmit a variable amount of torque. A mechanism is between the at least one MR fluid clutch apparatus and the body to convert the torque received from the at least one MR fluid clutch apparatus into a force on the body. Sensor(s) provide information indicative of a state of the body or structure. A controller receives the information indicative of the state of the body or structure and for outputting a signal to control the at least one MR fluid clutch apparatus in exerting a desired force on the body to control movement of the body according to a desired movement behavior.

Vehicles and steering systems for vehicles are provided. An exemplary steering system is provided for an automotive vehicle that includes road wheels and a rack mechanically coupled to the road wheels and laterally displaceable to change an orientation of the road wheels. The steering system includes a steering wheel mounted on a steering column and rotatable by a driver for inputting a steering command. The steering system also includes a lower column coupled to the rack. In the steering system, lateral displacement of the rack causes a rotational torque on the lower column. The steering system further includes a magneto-rheological coupling interconnected between the steering column and the lower column. The magneto-rheological coupling selectively communicates a desired portion of the rotational torque on the lower column to the steering column to provide haptic feedback to the steering column.

A steer-by-wire apparatus may include: a first rotating part rotated with a steering wheel; a second rotating part installed so as to be isolated from the first rotating part, and engaged with a first rack gear provided on a side surface of a gear bar; a sensor installed on each of the first and second rotating parts, and configured to measure at least any one of a rotation angle of the first rotating part, a rotation angle of the second rotating part and a torque value of the first rotating part; a controller configured to receive the measured value of the sensor; and a clutch configured to operate according to a control signal of the controller and synchronize rotations of the first and second rotating parts.

A steering control device configured to control a steering device, the steering device including a steering shaft to which a handle is detachably coupled and a motor configured to generate torque that is given to the steering shaft. The steering control device includes a processing circuit configured to execute a process for controlling driving of the motor. The process for controlling the driving of the motor includes a lock process of driving the motor such that a rotation position of the steering shaft is fixed at a specific position, in a state where the handle has been detached from the steering shaft.

The present embodiments relate to a steer-by-wire-type steering apparatus. The present embodiments may provide a steer-by-wire-type steering apparatus including: a locking member coupled to a shaft of a reaction motor and having locking teeth formed on an outer circumferential surface thereof; a pair of rotation-preventing members pivotally coupled by hinge axes at one ends thereof and having locking protrusions, which are supported by the locking teeth, formed at the opposite ends thereof; a cam rotatably coupled to a shaft of a driving motor so as to pivot the rotation-preventing members and having one side provided with one of a fixing recess and a fixing member inserted into the fixing recess; and a cam holder having one side, which faces the one side of the cam, provided with the other of the fixing recess and the fixing member.

An electromechanical motor vehicle power steering mechanism may include an electric motor and a control unit. The electric motor may be configured to provide a steering assist force. The control unit may be configured to control a current to the electric motor. Further, the control unit may include two redundant power supply units. Each of the two redundant power supply units may be connected to a vehicle battery. Also, the two power supply units may each comprise a primary winding and a secondary winding as part of a flyback transformer with a shared iron core. The shared magnetic core may be E-shaped with a middle leg and two side legs. The primary winding and the secondary winding of one of the two redundant power supply units may be wound around a first of the two side legs.

A steering apparatus for a steer by wire system includes a first motor and a second motor configured to provide a torque. A first planetary gear set is configured to receive the torque from the first motor and to generate a reaction torque required for steering. A second planetary gear set is configured to receive the torque from the steering wheel and the second motor, and to variably output a gear ratio for an input by the steering wheel depending on a rotation of the second motor. A stopping mechanism is configured to limit a maximum rotation angle of the steering wheel.

A friction clutch mechanism for a steering column of a vehicle is disclosed.

Provided is a steering controller configured to suppress deterioration of the operability of a steering wheel for steering steered wheels even when a driving voltage for a steering system has been decreased. When a clutch is in a disengaged state and steered wheels are steered by a steered-operation actuator while a reaction force is applied to steering wheel by a reaction-force actuator, if a driving voltage for the steered-operation actuator is decreased, a CPU opens relays and stops generation of torque by the steered-operation actuator. Meanwhile, a CPU engages the clutch and steers the steered wheels through cooperation between a steering torque input into the steering wheel and an assist torque generated by a reaction-force motor.

A device for preventing a reverse input includes a first housing, a second housing coupled with the first housing to define an internal space along with the first housing, an output shaft including an output disk disposed in the internal space and having one or more concave curved surfaces on an outer circumference surface of the output disk and an output shaft body configured to protrude from the output disk, an input shaft including an input disk having one or more concave grooves on an outer circumference surface thereof and an input shaft body disposed on a same rotation axis as a rotation axis of the output shaft body to protrude from the input disk, and one or more moving pins disposed on the concave grooves, respectively, to come into contact with the concave curved surfaces, respectively.