An automotive suspension for a sports car comprising a lower oscillating arm and a shock absorber having a relative end connected with a first intermediate part of the lower oscillating arm by means of a connecting rod having a first end hinged with said end of the shock absorber and a relative second end, opposite to the first end, hinged with said first intermediate part, locking means for locking said connecting rod in a stable position ranging between two extreme positions wherein said first end of the connecting rod is in a position close to or distal relative to the frame of the car.

An automotive suspension for a sports car comprising a lower oscillating arm and a shock absorber having a relative end connected with a first intermediate part of the lower oscillating arm by means of a connecting rod having a first end hinged with said end of the shock absorber and a relative second end, opposite to the first end, hinged with said first intermediate part, locking means for locking said connecting rod in a stable position ranging between two extreme positions wherein said first end of the connecting rod is in a position close to or distal relative to the frame of the car.

Provided is a vehicular suspension device that achieves both of improvement in driving stability and improvement in vehicle movement performance. The vehicular suspension device includes a suspension capable of adjusting a roll center height by control of an actuator, and a roll center controller. The controller includes a traveling state corresponding height determination unit configured to determine the roll center height of the suspension in accordance with a predetermined rule on the basis of vehicle speed information and road surface information, and an actuator controller configured to control the actuator so that the roll center height reaches the roll center height determined by the unit.

Provided is a vehicular suspension device that achieves both of improvement in driving stability and improvement in vehicle movement performance. The vehicular suspension device includes a suspension capable of adjusting a roll center height by control of an actuator, and a roll center controller. The controller includes a traveling state corresponding height determination unit configured to determine the roll center height of the suspension in accordance with a predetermined rule on the basis of vehicle speed information and road surface information, and an actuator controller configured to control the actuator so that the roll center height reaches the roll center height determined by the unit.

A suspension module having a subframe assembly. The subframe assembly may include a lower subframe that may pivotally support at least one lower control arm. An upper control arm mounting plate may be mounted to the lower subframe. The upper control arm mounting plate may pivotally support an upper control arm.

A suspension module having a subframe assembly. The subframe assembly may include a lower subframe that may pivotally support at least one lower control arm. An upper control arm mounting plate may be mounted to the lower subframe. The upper control arm mounting plate may pivotally support an upper control arm.

A suspension system includes: a trailing arm and a lower arm which are turnably connected to a chassis and are joined in such a way as to be displaceable relative to each other through a hinge mechanism; and a stabilizer. The suspension system includes a stabilizer link which connects the stabilizer to the trailing arm. A fitting point of the stabilizer link to the trailing arm is located behind a center axis of the hinge mechanism in a vehicle front-back direction, and a fastening point of the stabilizer and the stabilizer link is located above the fitting point in a vehicle up-down direction and inside the fitting point in a vehicle width direction.

A suspension system includes: a trailing arm and a lower arm which are turnably connected to a chassis and are joined in such a way as to be displaceable relative to each other through a hinge mechanism; and a stabilizer. The suspension system includes a stabilizer link which connects the stabilizer to the trailing arm. A fitting point of the stabilizer link to the trailing arm is located behind a center axis of the hinge mechanism in a vehicle front-back direction, and a fastening point of the stabilizer and the stabilizer link is located above the fitting point in a vehicle up-down direction and inside the fitting point in a vehicle width direction.

An independent suspension comprises upper and lower fork arms, elastic elements, shock absorber and fork arm positioning pivots. The fork arms are A-shaped, front ends of the fork arms respectively connect to upper and lower suspension points of a wheel, and rear ends of the fork arms connect to a vehicle frame through the elastic elements. The shock absorber mounts on top of the front end of the upper fork arm. Vehicle frame bearing pivot points and transmission parts are constructed on peripheries of the upper and lower fork arms. The arrangement absorbs bearing elastic forces by changing directions of force and the arms of force, to form multiple points supporting multiple elastic elements, so force applied on the wheel is distributed by multiple points, increasing average running speed. Increasing the number and arrangement of the elastic elements reduces vehicle height, optimizes space utilization and improves stability and running smoothness.

An independent suspension comprises upper and lower fork arms, elastic elements, shock absorber and fork arm positioning pivots. The fork arms are A-shaped, front ends of the fork arms respectively connect to upper and lower suspension points of a wheel, and rear ends of the fork arms connect to a vehicle frame through the elastic elements. The shock absorber mounts on top of the front end of the upper fork arm. Vehicle frame bearing pivot points and transmission parts are constructed on peripheries of the upper and lower fork arms. The arrangement absorbs bearing elastic forces by changing directions of force and the arms of force, to form multiple points supporting multiple elastic elements, so force applied on the wheel is distributed by multiple points, increasing average running speed. Increasing the number and arrangement of the elastic elements reduces vehicle height, optimizes space utilization and improves stability and running smoothness.