A steering mechanism intended for use in transport equipment, such as a truck, or a trailer, includes a steering knuckle on both sides of a body of the transport equipment. A king pin is fastened by articulation to the steering knuckles and a wheel of the transport equipment is fastened to each king pins. the steering knuckles being fastened by articulation to the body. The king pins are pivotable with respect to the steering knuckle to which they are fastened. The steering knuckles are pivotable so that when either of the steering knuckles pivots about the respective articulation arranged in the body, the king pin in the pivoting knuckle simultaneously remains un-pivoted with respect to the steering knuckle to which it is fastened. The other steering knuckle simultaneously remains un-pivoted and the king pin therein thus pivots with respect to the steering knuckle to which it is fastened.

A hydraulic control system for steering rear caster wheels of a work machine. The control system has a steering mode that proportionally controls the steering of rear caster wheels while compensating the circuit to keep steering performance independent from the load generated by the rear caster wheels, a no steering mode that maintains the position of the rear caster wheels in the absence of a steering command, and a freewheeling mode that permits the rear caster wheels to rotate freely 360°.

A method of braking an AGV, the AGV including a support structure and at least three drive units connected to the support structure, wherein each drive unit includes a wheel rotatable about a wheel axis and about a steering axis perpendicular to the wheel axis; an electric wheel motor arranged to drive the wheel about the wheel axis; a wheel sensor device arranged to determine a rotational position of the wheel about the wheel axis; an electric steering motor arranged to drive the wheel about the steering axis; and a steering sensor device arranged to determine a rotational position of the wheel about the steering axis; wherein the method includes positioning the wheels of the drive units in an invalid configuration; and position controlling each wheel about the respective steering axis in the invalid configuration.

Systems and methods are provided herein for operating a vehicle in a front dig mode. The front dig mode is engaged in response to determining that speed of the vehicle is below a speed threshold and determining that the amount that at least one of the front wheels of the vehicle is turned exceeds a turn threshold. While operating in the front dig mode, forward torque is provided to the front wheels of the vehicle. Further, resistance is applied to forward rotation of the inner back wheel of the vehicle. Yet further, forward torque is provided to the outer back wheel of the vehicle.

A steering stop mechanism including a fastener, a retention element disposed about the fastener, an adapter configured to receive at least a portion of the fastener therein, and a retention sleeve disposed about at least a portion of the fastener, the retention element, and the adapter. The retention sleeve is deformable and produced from a malleable material to allow the retention sleeve to conform to a shape of the retention element and the adapter during assembly of the steering stop mechanism with a working component.

Provided is a vehicle that can improve vehicle posture control or operation performance during accelerating turn. A vehicle is provided with: a left drive wheel and a right drive wheel connected to a motor; a required drive power amount input device for inputting a required drive power amount; and a required turn amount input device for inputting a required turn amount. The vehicle further includes a turn control device that adjusts a power difference between the left drive wheel and the right drive wheel on the basis of a time derivative value of the required drive power amount in addition to the required turn amount.

A machine includes a frame, a first steering arm, a second steering arm, a first hydraulic actuator coupled to the frame and the first steering arm, and a second hydraulic actuator coupled to the frame and the second steering arm. A first angle sensor measures a rotational displacement of the first hydraulic actuator relative to the first steering arm. A first link couples the first hydraulic actuator and the first sensor, and isolates movements other than the first rotational displacement. A second angle sensor measures a second rotational displacement of the second hydraulic actuator relative to the second steering arm. A second link couples the second hydraulic actuator and the second sensor, and isolates movements other than the second rotational displacement.

A machine includes a frame, a first steering arm, a second steering arm, a first hydraulic actuator coupled to the frame and the first steering arm, and a second hydraulic actuator coupled to the frame and the second steering arm. A first angle sensor measures a rotational displacement of the first hydraulic actuator relative to the first steering arm. A first link couples the first hydraulic actuator and the first sensor, and isolates movements other than the first rotational displacement. A second angle sensor measures a second rotational displacement of the second hydraulic actuator relative to the second steering arm. A second link couples the second hydraulic actuator and the second sensor, and isolates movements other than the second rotational displacement.

A steer-by-wire system for a motor vehicle includes at least two wheels which are steerable independently of one another in a normal operating mode of the steer-by-wire system, at least two steering actuators, each one being assigned to one of the steerable wheels and being configured for adjusting a steering angle of the particular steerable wheel, and at least one steering electronics system which is signally connected to the steering actuators and which is configured for controlling the steering actuators individually on the basis of steering commands.

A motorised vehicle comprises a first wheel located laterally on a first side of the vehicle, and a second wheel located laterally on a second side of the vehicle opposite the first side. The vehicle comprises a steering system configured to modify the orientation of the wheels and to turn the vehicle. The vehicle comprises a trajectory modifier configured to vary the speed of rotation of the first wheel and to modify the trajectory of the vehicle in the event of failure of the steering system.