A vehicle system includes a controller. The controller is configured to be communicably coupled to a plurality of actuators of a vehicle that facilitate repositioning a plurality of tractive elements coupled to a chassis of the vehicle. The controller is configured to (i) control the plurality of actuators to selectively reposition each of the plurality of tractive elements through a range of motion to attempt to maintain the chassis level and (ii) drive each of the plurality of actuators toward a mid-stroke position while continuing to attempt to maintain the chassis level and while the vehicle is moving.

A vehicle includes a chassis, a first actuator coupled to the chassis, a second actuator coupled to the chassis, a third actuator coupled to the chassis, a fourth actuator coupled to the chassis, and a fluid circuit. The fluid circuit is configured to facilitate selectively fluidly coupling the first actuator, the second actuator, the third actuator, and the fourth actuator in a plurality of different configuration. In each of the plurality of different configurations, two of the first actuator, the second actuator, the third actuator, and the fourth actuator are fluidly coupled together while the other two of the first actuator, the second actuator, the third actuator, and the fourth actuator are fluidly decoupled.

This invention relates to a chassis system for a vehicle comprising a frame configured to support a body of the vehicle. The frame comprises a pair of outer longitudinal members defining outer lateral sides of the chassis system. One or more suspension systems are connected between each of a plurality of wheel mounts and the frame, the wheel mounts configured such that the chassis system is supported on at least one pair of wheels. The outer longitudinal members are positioned on the outside of and adjacent to the wheels when the frame is in a ride position. The suspension systems are configured to selectively vary the height of the frame between the ride position and a raised position in which the outer longitudinal members are at a height above the top of the wheels.

A chassis for a lift device includes a base, an arm coupled to the base and configured to support a tractive element, and a plate extending from the arm at an upward angle. The arm includes a steering actuator interface configured to support an end of a steering actuator for the tractive element. The plate is configured to extend past the steering actuator.

A device and a method for influencing a dynamic property of at least one movably mounted body of two bodies coupled mechanically at least via a variably adjustable stiffness along a first force path. The invention includes a damping element with constant damping properties directly or indirectly coupled in series with the variably adjustable stiffness along the first force path Both bodies are mechanically directly or indirectly coupled via a second force path running parallel to the first force path along which at least one adjustable stiffness is incorporated. The damping property of the damping element and the adjustable stiffnesses are coordinated and configured so that a damping property assigned to the device for mechanical coupling can be varied exclusively by the adjustable stiffnesses.

A vehicle lowering system having a cargo surface with an adjacent pivoting arm is connected to a vehicle at a pivot point. The pivoting arm moves between a raised and a lowered position by an actuator that is affixed to a frame and the pivoting arm. The frame has an upper portion and a lower portion that provides structure for the portion of the frame that is beyond the pivot point and actuator. The pivot arm has a spindle that holds and allows a wheel to rotate. The spindle has an axis that is always located above the cargo surface. The actuator is movable between an extended position and a retracted position. When the actuator moves between the extended and retracted position, the pivoting arm moves the vehicle between a raised and a lowered position.

A chassis for a lift device includes a base, an arm, and a first actuator. The base has a first end and an opposing second end. The first end defines an arm interface and a pivot actuator interface. The arm includes a longitudinal portion pivotably coupled to the arm interface and a lateral portion extending from the longitudinal portion. The lateral portion defines a second pivot actuator interface. The lateral portion is configured to support a tractive element. The pivot actuator extends between the first pivot actuator interface and the second pivot actuator interface. At least a portion of a bottom surface of the lateral portion has a sloped profile.

A torsion spring bar system for a wheel suspension of a motor vehicle includes on each vehicle side a torsion spring bar which is oriented transversely to the vehicle longitudinal center and acts on each wheel guide element of the wheel suspension with variable pretension via an output lever positioned outwards with respect to the vehicle longitudinal center. The torsion spring bar is acted upon by an actuator with a torsional moment. The torsion spring bars on both vehicle sides are coupled to one another at their axially adjacent ends in the vehicle longitudinal center via at least one additional torsion spring element.

An assembly for supporting a vehicle chassis on a wheel of the vehicle includes a frame pivotably connected to the vehicle chassis at a connection location and a wheel attachment component slidingly coupled with the frame. The wheel attachment component is positioned on a first side of the connection location and is configured to pivot in unison with the frame and to move between a plurality of operating positions relative to the frame. A suspension component regulates motion transfer between the frame and the attachment component and is positioned on a second side of the connection location opposite the attachment component. An adjustment actuator is configured to shift the attachment component between any of the plurality of operating positions relative to the frame. The adjustment actuator is functionally independent of the suspension component.

A canned valve seal is disclosed. The valve seal is used within a gland formed in a piston body, the valve seal providing a fluid seal between the body and a valve when the valve is in a closed position, the valve seal includes a stiff component and a sealing material about the stiff component.