A vehicle has a frame, seats, two front and two rear suspension assemblies, two front and two rear wheels, and a motor. Each rear suspension assembly has a trailing arm, a knuckle pivotally connected to the trailing arm, a lower link having laterally outward and inward ends pivotally connected to the trailing arm at a first connection point and to the frame at a second connection point respectively, an upper link having laterally outward and inward ends pivotally connected to the trailing arm at a third connection point and to the frame at a fourth connection point respectively, and a toe link having laterally outward an inward ends pivotally connected to the knuckle at a fifth connection point and to the frame at a sixth connection point respectively. The fifth connection point is laterally further from a longitudinally and vertically extending center plane than the first and third connection points.

Vehicle suspension systems are described herein. An example wheel steering apparatus includes a steering actuator to couple to a rear axle, a tie rod, and a transfer link to couple the steering actuator and the tie rod. The steering actuator is positioned on a first side of a first longitudinal axis of the rear axle and the tie rod positioned on a second side of the first longitudinal axis of the rear axle opposite the first side.

A swing arm type suspension for a rear wheel of an off road vehicle can use two or three tie rods to control toe-in of the knuckle. The rear end of the swing arm is split between an upper clamping arm and a lower clamping arm defining an eye, with the knuckle connected to the upper and lower clamping arms by joint bearings, and with either the transmission shaft or one of the tie rods extending through the eye of the swing arm to the knuckle. The front of the swing arm can be connected to the vehicle frame using a cross-shaft joint. Camber, toe-in and half-track width are controlled to result in a smaller turning radius with better ride characteristics.

A frame for an off road vehicle includes main beams establishing a base plane. Mounting beams, which can be used to support forces from the swing arm of a rear suspension, are spaced outside the main beams and within the base plane, running longitudinally in line with the swing arms of the rear suspension. Right and left longitudinal beams start within the base plane, but rise to their trailing ends so as to not interfere with the suspension travel of the swing arms as they extend back inward over the swing arms. Front and rear support columns can further attach into, secure and support the mounting beams and the longitudinal beams. All of the beams and columns can be formed by cutting cylindrical tubing to length and then curving the cylindrical tubing, each piece within a single plane.

The invention relates to a mobile crane travel gear axle with suspensions, which are independent of one another, of the wheel carriers arranged on both sides of the travel gear frame of the mobile crane, wherein the suspensions each have at least one transverse link which couples the wheel carrier to the travel gear frame and which is connected to the travel gear frame so as to be rotatable about an axis extending substantially parallel to the longitudinal axis of the travel gear frame.

Vehicle integral bushing rear suspension systems are disclosed. An example rear wheel suspension includes a wheel carrier configured to mount a wheel of a vehicle, the wheel rotatable about a rotational axis, a lower transverse control arm coupled to the wheel carrier below the rotational axis, the lower transverse control arm including a first joint to be disposed on a vehicle structure and a second joint to be disposed on the vehicle structure, the second joint displaced from the first joint along a longitudinal axis, a camber transverse control arm coupled to the wheel carrier above the rotational axis, and a track transverse control arm coupled to the wheel carrier in front of the rotational axis, wherein the lower transverse control arm, the camber transverse control arm and the track transverse control arm couple the wheel carrier to the vehicle structure.

An outdoor power equipment unit includes a front wheel independent suspension system. The front wheel independent suspension system includes a frame, a first front wheel assembly, a second front wheel assembly, a first laterally-extending suspension arm pair, and a second laterally-extending suspension arm pair. The first laterally-extending suspension arm pair includes a first suspension arm and a second suspension arm, both coupled to the frame and the first front wheel assembly. The second laterally-extending suspension arm pair includes a third suspension arm and a fourth suspension arm, both coupled to the frame and the second front wheel assembly. Both the first suspension arm pair and the second suspension arm pair are configured to independently pivot about the frame such that each of the first front wheel assembly and the second front wheel assembly are vertically displaceable relative to the frame.

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 swing arm type suspension for a rear wheel of an off road vehicle can use two or three tie rods to control toe-in of the knuckle. The rear end of the swing arm is split between an upper clamping arm and a lower clamping arm defining an eye, with the knuckle connected to the upper and lower clamping arms by joint bearings, and with either the transmission shaft or one of the tie rods extending through the eye of the swing arm to the knuckle. The front of the swing arm can be connected to the vehicle frame using a cross-shaft joint. Camber, toe-in and half-track width are controlled to result in a smaller turning radius with better ride characteristics.

An active geometry control suspension may include a first link having one side connected to a wheel carrier engaged to a wheel and the other side extending along a width direction of a vehicle; a second link having one side connected to the wheel carrier and the other side extending in the width direction of the vehicle; a first lever having one side connected to the other side of the first link; a second lever having one side connected to the other side of the second link; a connection lever connecting the other side of the first lever and the other side of the second lever; and an actuator connected to the connection lever.