A suspension system for a work vehicle includes a shock absorber including a fluid, a coil positioned at least partially in the fluid, a sensor configured to detect a work status of the work vehicle, and a controller. The controller is configured to determine the work status of parked or operational based on the sensor, determine an electrical resistance of the coil in a shock absorber based on the work status, predict a temperature of a fluid in the shock absorber based on the electrical resistance of the coil, provide an electric current in the coil based on the predicted temperature of the fluid, determine the electrical resistance of the coil while the electric current is on, and terminate the electric current in the coil based on the work status and the predicted temperature.

A connecting arrangement for a stabilizer of a vehicle, with at least one lever that extends transversely to a longitudinal direction. The lever has a bearing eye provided with a non-circular inner circumferential contour. A torsion-bar spring with a rotation axis extends in the longitudinal direction. The torsion-bar spring has an outer circumferential contour, at least at one end, that matches the inner circumferential contour of the bearing eye and which fits into the bearing eye. The wall of the bearing eye is cut through by at least one slit extending in the longitudinal direction, by which two opposite wall sections of the wall are separated from one another. The two wall sections are pressed against the non-circular outer circumferential contour of the torsion-bar spring by at least one releasable clamping element.

A method for performing open-loop or closed-loop control of a driver's cab mount of a motor vehicle, wherein the driver's cab mount has dampers whose damper force can be adjusted, wherein the motor vehicle can be operated a first driving mode in which the motor vehicle automatically carries out vehicle guidance comprising both a longitudinal guidance operation and a transverse guidance operation of the motor vehicle, and in a second driving mode where the motor vehicle can be controlled by the driver, in which driving mode a driver of the motor vehicle is intended to carry out at least part of the vehicle guidance himself, wherein when the motor vehicle is operated in the first driving mode, the adjustable dampers of the driver's cab mount are actuated or adjusted in such a way that pitching or rolling movements are reduced compared to the second driving mode.

A vehicle with 3 or more wheels includes at least two wheels aligned on the same axis. The vehicle has an intermediate centreline plane between the wheels parallel to a direction of movement, including a mass suspended in relation to the wheels defining a passenger or containment compartment, and two suspension groups kinematically connecting the suspended mass to the two aligned wheels. An anti-roll stabiliser device has at least one compensation mass kinematically connected to the suspended mass via a guide and movable in relation thereto. The anti-roll stabiliser device has a drive of the compensation mass to distance or bring the compensation mass closer to the centreline plane on the side opposite the displacement of a barycentre of the suspended mass with respect to the same centreline plane, to oppose the displacement with respect to the centreline plane of the position of the barycentre of the suspended mass.

The invention relates to a damping system for a cabin of a movable work machine, wherein the cabin is supported to the frame of the work machine with suspension elements, the suspension elements forming a ROPS resistant structure and including: a first for fastening the cabin to the first end of the suspension element, a second stopper for fastening the frame to the second end of the suspension element, a guide element comprising a slide guide and a support arm, the slide guide and the support arm being arranged to move relative to each other, and the guide element having opposite ends, one of which is in the slide guide and the other is in the support arm, and one opposite ends is mechanically bound to the first end and the other is mechanically bound to the second end, a spring element, and a damping element.

The present disclosure relates to an air spring apparatus for use with a cabin of a vehicle. The apparatus has an upper assembly, a lower assembly, a shock absorber, a bladder, a flexible bumper element and a control element. The shock absorber has a piston rod protruding therefrom and extending through the other one of the upper and lower assemblies. The bladder is attached to the upper and lower assemblies. The flexible bumper element is secured to the piston rod adjacent one of the upper and lower assemblies, and secured to the other one of the upper and lower assemblies. The control element is secured to the flexible bumper element at a first end, and to a valve at a second end, and controls operation of the valve. The flexible bumper element can flex in response to torsional or tilting forces experienced by the one of the upper and lower assemblies, to thus help to limit these forces from being imparted to the control element.

A pneumatic suspension system for a vehicle is provided comprising a mounting arrangement for mounting a portion of the vehicle on a chassis; the mounting arrangement including at least one pneumatic spring to be arranged and coupled between the portion of the vehicle and the vehicle chassis. A vehicle state control system is provided that provides a pressure set value in the pneumatic spring and a pressure controller is arranged to a valve device alternatively for pressurizing or depressurizing the each pneumatic spring. The valve device comprises at least a first valve having a valve outlet coupled to the spring terminal and a valve inlet communicatively coupled to the pressure terminal. A support structure (102) distinct from the sealing edge (104) is provided arranged to providing supporting contact to the sealing face to counteract deformations of the sealing face.

A control unit for a vehicle that has a chassis and a driver's cab on the chassis, comprising a first data interface for receiving image data generated by an imaging sensor, a second data interface for receiving vehicle state data generated by a vehicle state sensor, an evaluation unit for evaluating the image data and/or the vehicle state data in order to generate a first control signal on the basis of the evaluation of the image data, which is configured to counteract a relative movement between the chassis and the driver's cab and/or generate a second control signal on the basis of the evaluation of the vehicle state data, which is configured to correct a setting of the imaging sensor, and a signal output unit for outputting the first and/or second control signals.