A vehicle includes a support structure and a suspension for an oscillatingly supported, rigid axle body. The suspension has a suspension device which is located between the axle body and the support structure and acts in a height direction of the vehicle. The vehicle further includes a plurality of coupling sites and a transverse link extending in a transverse direction of the vehicle. The transverse link is coupled to the support structure via a first link area and via a second link area and a pendulum support to the axle body. The transverse link includes a third link area which, with reference to the pendulum support in the transverse direction of the vehicle, is located opposite the first link area and is flexibly connected with a coupling site of the suspension device.

A method for determining an axle load on a vehicle axle of a tractor includes providing a power lift and a payload coupled thereto, driving the power lift by a hydraulic pump, setting a pump pressure of the hydraulic pump as a function of the coupled payload, detecting the pump pressure by a sensor, and determining the axle load as a function of the detected pump pressure from characteristic data which represents a relationship between the pump pressure and the weight of the payload.

A swingarm includes a first swingarm leg oriented along a first horizontal plane, a main body extending upward and outward from a second end of the first swingarm leg, and a second swingarm leg extending from a second end of the main body along a second horizontal plane. The swingarm also includes a first bearing holder coupled to a first end of the first swingarm leg and a second bearing holder coupled to a second end of the second swingarm leg. The first bearing holder includes a cavity oriented horizontally to form a first pivot axis. The second bearing holder includes a cavity oriented vertically to form a second pivot axis. The first and second bearing holders are of the same construction.

An embodiment of the present invention discloses a device (100) for connecting a wheel to a vehicle (620) comprising: an input shaft (620) able to be kinematically connected to an engine of a vehicle and having a rotation axis (C); an oscillating support (120) able to be hinged to a vehicle frame (T) along a predetermined horizontal hinge axis (B) parallel to and distanced from the rotation axis (C) of the input shaft (620); an auxiliary shaft (125) rotatably associated to the oscillating support (120) according to a rotation axis (A) parallel to and distanced from the hinge axis (B); a wheel-bearing hub (110) rotatably associated to the oscillating support (120) according to a rotation axis (A) parallel to and distanced from the hinge axis (B); first transmission means (625) able to transmit the motion from the input shaft (620) to the auxiliary shaft (125); second transmission means (130) able to transmit the motion of the auxiliary shaft (125) to the wheel-bearing hub (110).

An auto-leveling drive axle device for a wheel tractor, and leveling method. The device comprises a transmission device and a leveling device. The device of the present invention changes only a vertical position of a drive axle with respect to a wheel, and a wheel shaft distance and wheel center spacing are not changed, thus improving traveling stability of a vehicle.

A plurality of traveling wheels are supported via expandable/contractible tubular support members to a vehicle body frame. A hydraulic operation type vehicle height adjustment mechanism is provided for each one of the traveling wheels, the vehicle height adjustment mechanism being capable of switching a relative height of the traveling wheel relative to the vehicle body frame within a predetermined length range by expanding/contracting the support member by a hydraulic cylinder. There are provided a hydraulic control valve capable of controlling feeding state of work oil to each one of the plurality of hydraulic cylinders, a controlling section for controlling an operation of the hydraulic control valve to bring the vehicle body to a target state via vehicle height adjustment by the hydraulic cylinder in response to a change in the posture of the vehicle body and a plurality of accumulators connected oil chambers of the respective plurality of hydraulic cylinders.

A work vehicle, comprises: an operation section occupiable by an operator; a cabin accommodating the operation section; left and right suspension mechanisms via which a body of the work vehicle supports a left portion and a right portion of the cabin; and left and right lateral rods configured to allow the cabin to move upward and downward relative to the body and restrain the cabin from moving leftward and rightward relative to the body.

An adjustable steering stop includes a chassis stop configured to be coupled to a chassis member of a vehicle and a knuckle stop configured to be coupled to a steering knuckle. The chassis stop and the knuckle stop together define a steering limit location where the knuckle stop contacts the chassis stop. The adjustable steering stop further includes an adjustment actuator coupled to one of the chassis stop or the knuckle stop to move the chassis stop or the knuckle stop thereby changing the steering limit location.

A wheeled work vehicle (1) comprises a forward chassis part (4) and a rearward chassis part (5) pivotally connected about a substantially vertically extending primary pivot axis (7) for steering thereof. A pair of forward ground engaging wheels (29) are carried on a forward suspension unit (32), and a pair of rearward ground engaging wheels (30) are carried on a rearward suspension unit (33). The forward suspension unit (32) is pivotally connected to the forward chassis part (4) by a pair of main forward transverse pivot shafts (63) pivotally coupled to the forward chassis part (4) by corresponding main forward pivot mountings (65). The main forward transverse pivot shafts (63) defines a main forward transverse pivot axis (59) about which the forward suspension unit (32) is pivotal relative to the forward chassis part (4). The forward suspension unit (32) comprises a pair of spaced apart trailing arms (35) which are joined by a torsion shaft (68) of tubular steel, which is rigidly connected to the trailing arms (35). The torsion shaft (68) defines a torsional axis (70), and permits limited upward and downward pivotal type torsional deflection of the trailing arms (35) relative to each other. The rearward suspension unit (33) is substantially similar to the forward suspension unit (32) and is coupled to the rearward chassis part (5) about a pair of main rearward transverse pivot shafts (87) in a similar manner as the forward suspension unit (32) is coupled to the forward chassis part (4).

A spring strut for a vehicle suspension system includes a spring cylinder defining a cylinder chamber and a spring piston longitudinally displaceable in the spring cylinder. The spring piston subdivides the cylinder chamber into a first and a second outer working chamber. The spring cylinder includes an inner plunger which subdivides a piston chamber formed by the spring piston into a first and a second inner working chamber. The first inner working chamber is simultaneously formed by subdividing the cylinder chamber by means of the spring piston.