An all-terrain vehicle is provided. The vehicle includes a lateral stabilizer bar and a shock absorber. The lateral stabilizer bar further includes a main bar, two side bars and ball-pin connecting rods. The side bars are connected to two sides of the main bar respectively and bent backward relative to the main bar, ends of the side bars are disposed on a suspension assembly, the main bar is disposed at the front end of a frame and located in front of a radiator, the ends of the two side bars are connected to the ball-pin connecting rods respectively, and the ball-pin connecting rods are disposed on the upper rocker arm. The side bars and the ball-pin connecting rods of the lateral stabilizer bar are located on an inner side of the shock absorber.

The present disclosure discloses an all-terrain vehicle which includes: a frame, a left-front suspension assembly connected with a left side of the frame and including a left-upper rocker arm and a left-lower rocker arm, the left-upper rocker arm is located above the left-lower rocker arm; a right-front suspension assembly connected with a right side of the frame and including a right-upper rocker arm and a right-lower rocker arm, the right-upper rocker arm is located above the right-lower rocker arm; a lateral stabilizer bar mounted on the frame and arranged above the left-upper rocker arm and the right-upper rocker arm, and a steering gear mounted on the frame and located below the lateral stabilizer bar.

The present disclosure discloses an all-terrain vehicle which includes: a frame, a left-front suspension assembly connected with a left side of the frame and including a left-upper rocker arm and a left-lower rocker arm, the left-upper rocker arm is located above the left-lower rocker arm; a right-front suspension assembly connected with a right side of the frame and including a right-upper rocker arm and a right-lower rocker arm, the right-upper rocker arm is located above the right-lower rocker arm; a lateral stabilizer bar mounted on the frame and arranged above the left-upper rocker arm and the right-upper rocker arm, and a steering gear mounted on the frame and located below the lateral stabilizer bar.

An off-road vehicle includes a frame; front and rear wheels; a front suspension assembly; a front torsion bar assembly, a rear suspension assembly and a rear torsion bar assembly. The front suspension assembly comprises a front lower rocker arm, a front upper rocker arm, and a front wheel shaft support assembly mounted between the front lower and the front upper rocker arms. The front torsion bar assembly is located above the front upper rocker arm, and is movably connected to the front upper rocker arm. The rear suspension assembly comprises a rear lower rocker arm, a rear upper rocker arm, a control arm assembly, and a rear wheel shaft support assembly mounted between the rear lower and rear upper rocker arms. The rear torsion bar assembly is located between the rear upper and lower rocker arms, and is movably connected to the rear upper rocker arm.

An off-road vehicle includes a frame; front and rear wheels; a front suspension assembly; a front torsion bar assembly, a rear suspension assembly and a rear torsion bar assembly. The front suspension assembly comprises a front lower rocker arm, a front upper rocker arm, and a front wheel shaft support assembly mounted between the front lower and the front upper rocker arms. The front torsion bar assembly is located above the front upper rocker arm, and is movably connected to the front upper rocker arm. The rear suspension assembly comprises a rear lower rocker arm, a rear upper rocker arm, a control arm assembly, and a rear wheel shaft support assembly mounted between the rear lower and rear upper rocker arms. The rear torsion bar assembly is located between the rear upper and lower rocker arms, and is movably connected to the rear upper rocker arm.

A method of operating an adjustable roll stabilizer for a motor vehicle. The stabilizer has an actuator which can be rotated through a system angle about a rotational axis to apply a system torque and rotate two stabilizer sections relative to one another about the axis. The stabilizer sections are coupled at a radial distance from the axis to a respective wheel suspension, and depending on the system angle and under the external influence of movements of the wheel suspensions, twist relative to one another through a stabilizer angle. In the context of a perturbation magnitude regulation, the actuator is controlled based on the stabilizer angle determined from height levels of the wheels, by virtue of a stored relationship for the roll stabilizer and/or motor vehicle. The plausibility of the stored relationship between the wheel height levels and the stabilizer angle is checked by a model calculation.

A vehicle front structure basically includes a vehicle frame, an upper suspension arm, a lower suspension arm, a sway bar and a rack and pinion steering. The upper suspension arm is pivotally coupled to the vehicle frame about first and second upper pivot points. The lower suspension arm is pivotally coupled to the vehicle frame about first and second lower pivot points. The sway bar is attached to the upper suspension arm and located above the upper suspension arm. The rack and pinion steering arranged between the upper and lower suspension arms. The rack and pinion steering is located adjacent the second upper pivot point and between the first and second upper pivot points with respect to a longitudinal vehicle direction.

A vehicle front structure basically includes a vehicle frame, an upper suspension arm, a lower suspension arm, a sway bar and a rack and pinion steering. The upper suspension arm is pivotally coupled to the vehicle frame about first and second upper pivot points. The lower suspension arm is pivotally coupled to the vehicle frame about first and second lower pivot points. The sway bar is attached to the upper suspension arm and located above the upper suspension arm. The rack and pinion steering arranged between the upper and lower suspension arms. The rack and pinion steering is located adjacent the second upper pivot point and between the first and second upper pivot points with respect to a longitudinal vehicle direction.

A sway-bar actuator for a vehicle includes a motor that rotationally operates a lead rod to axially operates a push rod. Operation of the push rod axially operates an attachment fork between an engaged position and a disengaged position. The engaged position is characterized by a unified operation of opposing stabilizing bars. The disengaged position is characterized by independent rotational operation of the opposing stabilizing bars. A sensor rod is coupled to and operates axially with the attachment fork. A sensor assembly has a rotator and a sensor magnet. Axial operation of the sensor rod produces a rotational operation of the sensor magnet. The sway-bar actuator includes an encoder, where a rotational position of the sensor magnet relative to the encoder corresponds to an axial position of the attachment fork and the push rod relative to the engaged and disengaged positions.

A bushing assembly for a stabilizer bar in a vehicle includes a split ring defining a passageway engaging with an outer surface of the stabilizer bar, an outer diameter surface, a first split ring end, a second split ring end, and at least one axial retention flange disposed at either the first split ring end or the second split ring end. The bushing assembly includes an elastomer bushing defining an inner diameter, an outer diameter, a first bushing end, a second bushing end, a first axial flange disposed at the first bushing end, and a second axial flange at the second bushing end. At least one of the first axial flange and the second axial flange abut against the at least one axial retention flange of the split ring to create a zero clearance condition. The bushing assembly also includes a strap clamp securing the bushing assembly to the vehicle.