A suspension system for a vehicle includes at least two torsion bars, each of which are connected on their first end to respective wheel suspensions that are arranged on opposite lateral sides of the vehicle. Movement of the wheel suspensions produces torque in the respective torsion bars. Each of the torsion bars are connected on their second ends to a frame of the vehicle through a damper system. Movement of the wheel suspensions produces torque in the respective torsion bar. The damper system selectively applies resistance to the torque in the torsion bars to selectively provide active variable spring rates to the wheel suspension, which application of resistance may be coordinated amongst the various torsion bars to inhibit roll of the vehicle during a turning maneuver or to increase occupant comfort when the vehicle encounters a bump or hole.

A suspension system for a vehicle includes at least two torsion bars, each of which are connected on their first end to respective wheel suspensions that are arranged on opposite lateral sides of the vehicle. Movement of the wheel suspensions produces torque in the respective torsion bars. Each of the torsion bars are connected on their second ends to a frame of the vehicle through a damper system. Movement of the wheel suspensions produces torque in the respective torsion bar. The damper system selectively applies resistance to the torque in the torsion bars to selectively provide active variable spring rates to the wheel suspension, which application of resistance may be coordinated amongst the various torsion bars to inhibit roll of the vehicle during a turning maneuver or to increase occupant comfort when the vehicle encounters a bump or hole.

A load sensor system including one or more of a vehicle suspension including a pair of beams outwardly extending from a vehicle axle, a pair of air suspension assemblies correspondingly coupled between the pair of beams and a vehicle frame, where each of the air suspension assemblies includes a load sensor capable of generating a load signal, a load sensor computer communicatively coupled to the load sensor having a load sensor program including a load calculator, and a central computer communicatively coupled to the load sensor computer having a central program executable to receive the load calculated by the load sensor computer.

A load sensor system including one or more of a vehicle suspension including a pair of beams outwardly extending from a vehicle axle, a pair of air suspension assemblies correspondingly coupled between the pair of beams and a vehicle frame, where each of the air suspension assemblies includes a load sensor capable of generating a load signal, a load sensor computer communicatively coupled to the load sensor having a load sensor program including a load calculator, and a central computer communicatively coupled to the load sensor computer having a central program executable to receive the load calculated by the load sensor computer.

The invention relates to a top mount assembly of a suspension strut, the assembly comprising: a bearing and a filtering sub-assembly abutting the bearing, which includes: a filter block; a lower support having a central portion abutting a lower face of the filter block and a peripheral portion; a cover including a central portion abutting an upper face of the filter block and a peripheral portion abutting the annular peripheral portion of the lower support. The peripheral portion of the cover is provided with fastening openings arranged radially outside the bearing to secure the filtering sub-assembly to a body element of the vehicle.

The invention relates to a top mount assembly of a suspension strut, the assembly comprising: a bearing and a filtering sub-assembly abutting the bearing, which includes: a filter block; a lower support having a central portion abutting a lower face of the filter block and a peripheral portion; a cover including a central portion abutting an upper face of the filter block and a peripheral portion abutting the annular peripheral portion of the lower support. The peripheral portion of the cover is provided with fastening openings arranged radially outside the bearing to secure the filtering sub-assembly to a body element of the vehicle.

A suspension assembly for a vehicle having a frame includes a control arm, knuckle, spring, damper, and control module. The control arm is pivotably coupled to the frame. The knuckle is coupled to the control arm and supports a wheel hub for rotation relative to the knuckle. The spring is mounted between the frame and the control arm or the knuckle. The damper has an adjustable damping force and includes a first end mounted to the frame and a second end mounted such that a change in caster angle of the knuckle extends or contracts the damper. The control module is in communication with the damper and configured to adjust a damping force of the damper based on an actual or predicted change in caster angle of the knuckle. The control module is configured to increase the damping force in a direction that resists a change in the caster angle.

A shock damper is disposed between a vehicle body side and a wheel side. A suspension control device calculates a damping force of the shock damper on the basis of vehicle height information and controls the damping force. A steering system includes an electric motor and a steering control device that controls the electric motor, and assists steering effort of the driver through the electric motor. The suspension control device calculates the vibration generated in a steering on the basis of a detected value of a vehicle height sensor and creates a signal for generating steering torque that reduces the generated vibration. The suspension control device outputs the created signal to the steering control device. Steering torque for cancelling steering vibration is accordingly outputted from the electric motor of the steering system.

A camber control system of a vehicle includes a camber actuator configured to adjust a camber angle of a wheel of the vehicle. A camber control module is configured to: determine a target camber angle for the wheel based on one or more operating parameters; and actuate the camber actuator based on the target camber angle, thereby adjusting the camber angle of the wheel toward the target camber angle.

This disclosure relates to a suspension thrust bearing device, for use with a suspension spring in an automotive suspension strut of a vehicle. The device comprises a bearing having upper and lower annular bearing members in relative rotation, and a damping element made of resilient material and interposed between the lower annular bearing member and the suspension spring. The damping element comprising at least one deflecting flange for reducing any ingress of water and other pollutants between the upper and lower annular bearing members. The damping element is provided with an annular groove open axially towards the suspension spring, said annular groove radially defining a spring support surface on inner side, and the said deflecting flange on outer side.