A utility vehicle includes a plurality of ground-engaging members, a frame, a powertrain assembly, a front suspension assembly, and a rear suspension assembly. A cargo bed may be supported by the frame at the rear of the vehicle. The vehicle also includes an operator seat and at least one passenger seat positioned within an operator area. In one embodiment, the vehicle includes doors to enclose the operator area.

A suspension structure of a utility vehicle includes a frame, a wheel, and a trailing arm including an arm extending anteroposteriorly and supported by the frame, a knuckle rotatably supporting the wheel, and a rotary shaft configured to angularly displace the knuckle in a vehicle width direction with respect to the arm.

A vehicle includes a vehicle body, a road wheel, and a suspension corner connecting the road wheel to the vehicle body. The suspension corner includes a suspension arm connected to the road wheel and to the vehicle body, and also includes a suspension force decoupling system disposed on an axis extending between the suspension arm and the vehicle body. The suspension force decoupling system includes an actuator having an actuator mass arranged on the axis that is configured to output an actuator force in opposite directions along the axis in response to an actuator control signal. The system also includes a compliant element connected along the axis to the actuator mass and one of the body and the suspension arm, and providing a predetermined level of mechanical compliance. A controller determines and generates the actuator force in response to a threshold acceleration of the vehicle body.

A ridable kart can have a body that supports a front wheel and movable rear wheels. The kart can include a motor that supports and drives the rear wheels. The motor and rear wheels are configured to tilt and rotate relative to the body of the kart. The body of the kart includes a concave space in which the front and rear wheels are positioned so that they are at least partially concealed by the body when viewed from the side of the kart.

A vehicle structure for a two-track vehicle provided with an auxiliary frame for a vehicle axle, in particular a rear axle, which is provided with a wheel suspension on the articulation points for wheel link on the superstructure side, which are connected to articulation points on the wheel carrier side, connected to a wheel carrier carrying a vehicle wheel, and which is equipped with a spring and/or damper unit, which is supported between a vehicle superstructure and the wheel suspension, wherein the wheel frame is connected to at least one auxiliary frame bearing in a manner that is decoupled from oscillations at the vehicle superstructure, and wherein the wheel and/or damping unit is equipped with a rotational damper. According to the invention, the auxiliary frame bearing is provided with a connection point at which is connected the rotational damper.

A driverless transport system comprising a chassis (1), drive wheels (2) and jockey wheels (3), wherein, on each of a first side of the chassis (1) and a second side of the chassis (1) opposite the first side, a floating axle (4) arranged in the longitudinal direction is pivotably connected to the chassis (1) at a connection point (5) assigned in each case, a drive wheel (2) being arranged at one end of each of the floating axles (4) and a jockey wheel (3) being arranged at the opposite end of each of the floating axles (4), the driverless transport system additionally having a floating axle (6) arranged in the transverse direction which is aligned transversely to the two floating axles (4) arranged in the longitudinal direction and is pivotably or fixedly connected to the chassis (1) at an assigned connection point (5), a jockey wheel (3) being arranged at each end of the floating axle (6) arranged in the transverse direction.

A control arm system is provided. The system includes an upper control arm, a lower control arm longer than the upper control arm, a spindle, and a bracket coupled to a frame. The upper control arm and the lower control arm are coupled between the bracket and the spindle. A pivot point of the upper control arm and the bracket is closer to the spindle than a pivot point of the lower control arm and the bracket. The control arm system is moveable between a compressed position and an extended position with a neutral position between the compressed position and the extended position. A tire coupled to the spindle is rotated into a negative camber orientation when the control arm system is in a compressed position or in an extended position. A track width is maintained in the compressed, neutral, and extended positions.

A modular chassis is provided for an off-road vehicle to improve assembly, servicing, and repairing of a drivetrain of the off-road vehicle. The modular chassis includes a chassis to support components of the off-road vehicle. A front frame module couples with a front of the chassis, and a rear frame module couples with a rear of the chassis. The front frame module supports lower suspension arms of the off-road vehicle by way of inboard bushing joints. The front frame module supports at least a steering gear and a front differential of the off-road vehicle. The rear frame module is a tube-frame structure that supports components of the off-road vehicle. A lower portion of the rear frame module extends rearward and acutely upward to a top frame member that couples with upper side portions of the chassis. Several cross-members impart structural integrity to the rear frame module.

A front suspension system is provided for a front-wheel drive vehicle having a drive shaft for driving a front wheel. The front suspension system includes a suspension device configured to be connected to the vehicle, a control arm configured to be connected to the vehicle, and a yoke mount configured to connect the suspension device to the control arm. The yoke mount has first and second legs that receive the drive shaft therebetween when the front suspension system is mounted on the vehicle.

A rear suspension for a vehicle includes a knuckle for supporting a rear wheel of the vehicle, and the knuckle defines an opening. The rear suspension system further includes two suspension devices configured to be connected to the vehicle and an upper portion of the knuckle, such that each suspension device is oriented along an upright axis when the rear suspension system is mounted on the vehicle. In addition, the rear suspension system includes a control arm having a first portion configured to be connected to the vehicle and a second portion configured to extend between the axes of the suspension devices and into the opening of the knuckle when the rear suspension system is mounted on the vehicle.