An arrangement for pivotally coupling a saddle member of a main frame with an equalizer bar of a machine. The saddle member includes one or more bores. The equalizer bar includes a central portion. The arrangement includes a pin and one or more bearings. The pin extends through each of the one or more bores and couples the saddle member with the central portion of the equalizer bar. The one or more bearings positioned inside each of the one or more bores for rotatably supporting the pin.

Aspects of the present disclosure relate to a locking control method for a pivot axle of a wheeled working machine including: determining, using a multibody simulation model, a current posture and motion state of the working machine and static and dynamic forces acting on the working machine; determining a relevant tipping line based on a current locking status of a pivot axle of the working machine; calculating torques acting on the working machine based on the information on current posture, motion state, static and dynamic forces; determining a control command for a pivot axle locking mechanism of the working machine based on the calculated torques and the tipping line; and providing the control command to a pivot axle locking mechanism.

A vehicle that includes a first rotatable frame that includes a first wheel assembly and a second wheel assembly. The vehicle also includes a second rotatable frame that includes a third wheel assembly and a fourth wheel assembly. The vehicle further includes a base frame configured to support a weight-bearing load. The vehicle further includes an axle member engaging the first rotatable frame, the second rotatable frame, and the base frame, wherein the first rotatable frame is rotatable about the axle member relative to the base frame and independent of the second rotatable frame, and the second rotatable frame is rotatable about the axle member relative to the base frame and independent of the first rotatable frame.

An off-road vehicle includes a chassis, an axle carriage, a rigid axle and a pair of suspension cylinders. The axle carriage is attached to or forms a part of the chassis, and includes a generally vertically arranged slot. The rigid axle is mounted to the axle carriage with a wheel hub at each end thereof, and is vertically movable relative to the axle carriage. The suspension cylinders are connected between the axle carriage and axle, and are operable to move the axle in vertical directions relative to the axle carriage. The off-road vehicle is characterized in that the axle includes a first pair of roll angle stops which engage the axle carriage when the axle is at or near a fully lowered position relative to the axle carriage, and a second pair of roll angle stops which engage the axle carriage when the axle is at or near a fully raised position relative to the axle carriage.

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 vehicle includes a chassis, an axle pivotally coupled to the chassis such that the axle can tilt from side to side relative to the chassis, a tilt-angle sensor configured to detect a tilt angle of the axle relative to the chassis, and steerable hubs carried by the axle. Each hub is configured to rotate about steering axes relative to the axle, and a steering-angle sensor is configured to detect a steering angle of at least one hub relative to the axle. A control system limits a maximum steering angle of the hubs based at least in part on a size of tires or tracks carried by the steerable hubs and the detected tilt angle of the axle. A method includes detecting a tilt angle of the axle relative to the chassis and limiting the maximum steering angle of the hubs.

Aspects of the present disclosure relate to a locking control method for a pivot axle of a wheeled working machine including: determining, using a multibody simulation model, a current posture and motion state of the working machine and static and dynamic forces acting on the working machine; determining a relevant tipping line based on a current locking status of a pivot axle of the working machine; calculating torques acting on the working machine based on the information on current posture, motion state, static and dynamic forces; determining a control command for a pivot axle locking mechanism of the working machine based on the calculated torques and the tipping line; and providing the control command to a pivot axle locking mechanism.

All-terrain construction vehicles are provided that can include: a central frame; a pair of axles, each of the axles extending substantially normally across an axis of the central frame and pivoting in relation thereto; and at least two pairs of wheels. The vehicles can include at least two pairs of levelers. The vehicles can include out-rigging operatively extending above the one axis and between an operator cab and fluid pump unit in at least one configuration, the pump and fluid therefrom operatively coupled to the axles and wheels, the axles, wheels, and pump being operatively controlled via an operator interface within the operator cab. The vehicle can include levelers along the one side of the axis of the frame configured to support a utility pole above the hydraulic fluid pump unit.

A working vehicle includes a machine body frame to which an engine is fixed, a front axle case that supports an axle of a front wheel and is rockable about a rocking shaft, a suspension device that absorbs vibration transmitted from the front axle case to the machine body frame, and a support member that is fixed to the machine body frame so as to be located below the engine, supports the rocking shaft, and defines a routing space in which a linear member (first hose, second hose extending in a front-rear direction can be routed between the support member and the engine.

A guided vehicle includes: a first wheel section positioned at a front end portion of a base; and second and third wheel sections which are independent from each other. The first wheel section includes a left-right frame body, and swivel wheels arranged on left and right portions of the left-right frame body. An intermediate position between the swivel wheels in the left-right frame body is supported to be swingable about a front-rear axis relative to the base. Each of the second wheel section and the third wheel section includes a front-rear frame body, and a driving wheel and a swivel wheel which are respectively arranged at a front portion and a rear portion of the front-rear frame body. An intermediate position between the driving wheel and the swivel wheel of each front-rear frame body is supported to be swingable about the left-right axis and the front-rear axis relative to the base.