A vehicle suspension device includes a wheel body on which a wheel and tire unit is mounted, a steering drive unit configured to transmit a driving force to rotate the wheel body in a lateral direction of a vehicle body, so that the wheel and tire unit rotates together with the wheel body, and a wheel moving unit disposed on the vehicle body to be movable in a front-back direction, configured such that a position thereof changes in a top-bottom direction, and connected to the wheel body to support the wheel body, so that a position of the wheel body is changed in response to the wheel moving unit moving in the front-back direction and changing the position in the top-bottom direction.

A vehicle suspension having a first load-bearing component assembly and a second load-bearing component assembly. The first and second load bearing component assemblies are adapted to be transversely positioned across from each other on a vehicle chassis. A directionally-dependent heave spring assembly is adapted to be transversely secured to a vehicle chassis, the heave spring assembly is coupled to the first load-bearing component assembly and to the second load-bearing component assembly and exhibits resiliency in opposition to upward vertical movement of both wheel hub assemblies relative to their rest states, and exhibits substantially no resiliency in opposition to downward vertical movement of both wheel assemblies relative to their rest states.

An assembly includes a suspension link, an arm, an actuator, and a lock. The arm is connected to the suspension link. The arm includes a plurality of holes. The actuator is connected to the arm. The lock includes a pin releasably engageable with the plurality of holes of the arm.

A caster angle adjustment device for a vehicle includes a variable lower arm connected to multiple points of a subframe via connection parts and connected to a steering knuckle at a single point via one of the connection pails, any one of the connection pails connected to the subframe being movably connected to the subframe to be changed in shape, and an actuator provided in the subframe and connected to the connection part movably connected to the subframe and configured to move a position of the connection part, so that a position of the steering knuckle is moved through the shape change of the variable lower arm to change a caster angle.

A mobile drive unit includes a pivot between the front chassis unit and the rear chassis unit, thereby diminishing the total height of the unit.

A vehicle suspension cage is provided and more particularly a dirt track racing rear axle birdcage style cage having features facilitating rapid suspension tuning and adjustment typically experienced during competitive events to accommodate varying track and handling conditions. A particular advantage is that adjustment of the suspension cage is accomplished without unloading the suspension thereby eliminating lifting the vehicle off the ground or removing the vehicle weight from the suspension. A four-link dirt modified suspension cage configuration embodiment and method of adjustment is provided; however, the suspension cage is adaptable to a variety of configurations and embodiments.

An extension-retraction link includes: a stationary shaft having a tubular shape; a first universal joint that connects the stationary shaft to a vehicle body side member; a movable shaft that can slide with respect to the stationary shaft; a second universal joint that connects the movable shaft to a hub carrier; and an actuator that moves the movable shaft. The movable shaft includes: a first plane surface; a second plane surface making an angle with respect to the first plane surface; a third plane surface opposite the first plane surface; and a fourth plane surface opposite the second plane surface. The stationary shaft includes: first to fourth bushes in contact with the first to fourth plane surfaces, respectively; a first elastic member pressing the third bush to the third plane surface; and a second elastic member pressing the fourth bush to the fourth plane surface.

An assembly includes a suspension link, an arm, an actuator, and a lock. The arm is connected to the suspension link. The arm includes a plurality of holes. The actuator is connected to the arm. The lock includes a pin releasably engageable with the plurality of holes of the arm.

A wheel alignment mechanism having a control arm connector, which is adapted for connection to a vehicle suspension control arm positioned between a vehicle chassis and a vehicle wheel, and which has an elongate portion; an inner support frame having a first surface and a second surface on a side of the inner support frame opposing the first surface, the elongate portion of the control arm connector positioned against the first surface at a select one of a first set of plural mounting locations on the first surface, with the first set of plural mounting locations being disposed in a first direction; and an outer support frame adapted to receive a wheel mounting, the connector having a third surface, the second surface of the inner support frame being positioned against the third surface at a select one of a second set of plural mounting locations on the third surface, and with the second set of plural mounting locations being disposed in a second direction approximately perpendicular to the first direction. Means are provided for securing the control arm connector to the inner support frame and the inner support frame to the outer support frame.

Provided is a trailing arm riding mower suspension system that includes trailing arms adapted to support hydraulic motor units and having leading ends pivotally coupled to a mower frame by way of leading end spherical joints and trailing ends having hydraulic drive unit mounts, where the trailing arms are adapted to pivot about leading end pivot locations defined by the leading end spherical joints.