A work vehicle includes a hydraulic actuator, a control valve, a pressure sensing unit, a force imparting component, and a controller. The hydraulic actuator varies a steering angle. The control valve controls flow of fluid supplied to the hydraulic actuator. The operation member is configured to be operated by an operator and to control the control valve when varying the steering angle. The pressure sensing unit senses a pressure produced by the hydraulic actuator. The force imparting component imparts an assisting force or a counterforce to operation of the operation member. The controller controls the force imparting component so as to generate resistance to operation of the operation member based on a pressure value sensed by the pressure sensing unit.

A pedestrian truck (50) steered with a tiller (56) is operable in a first mode where a controllable front wheel (64) is aligned generally parallel with a front-rear center line of the truck, or a second mode where the wheel is generally perpendicular to the front-rear center line. A steering controller can operate in either a normal steering mode to steer the rear steerable wheel (52) in the same sense (clockwise or anticlockwise) as the tiller is rotated and in an alternate steering mode to steer the rear steerable wheel in the opposite sense to the rotation of the tiller. A steering mode selector is provided which automatically engages the alternate steering mode when the truck is in the second mode of operation and either (i) the tiller is positioned on the same side of the center line as the controllable front wheel and the drive direction is such that the tiller leads the truck (FIGS. 12-14), or (ii) the tiller is positioned on the same side of the center line as the castor front wheel (58) and the drive direction is such that the tiller trails the truck (FIGS. 4, 5).

A component moving system may include a cart, and a component support assembly coupled to the cart. The component support assembly may include a component cradle moveable in first linear translational directions, second linear translational directions that are orthogonal to the first linear translational directions, third linear translation directions that are orthogonal to the first and second linear translational directions, and first rotational directions.

The invention provides a modification system for modifying the steering ratio for a vehicle having a tiltable telescopic boom arm (6), the vehicle having steered wheels (11), a steering wheel, and a steering transmission device serving to transmit steering movement between the steering wheel and the steered wheels (11) with a steering ratio R=Alpha/Beta, where Beta is the steering angle of the wheels, and Alpha is the turning angle of the steering wheel. The system includes a sensor configured to determine a parameter relating to the telescopic arm, e.g. an angle sensor for sensing the angle (Af) formed between the telescopic arm and the bearing plane of the wheels of the vehicle on the ground, and/or a sensor for sensing the length (L6) of the telescopic arm, and a control module for controlling the steering ratio that is configured to modify the steering ratio R as a function of said parameter relating to the telescopic arm. The invention also provides a wheeled vehicle fitted with such a steering ratio modification system.

The present invention relates to a hydraulic steering system for a vehicle, in particular an industrial truck, comprising: a steering cylinder having two chambers and a hydraulic connection at each of the two chambers for activating a steering movement of at least one wheel of the vehicle; at least one hydraulic pump; at least one hydraulic tank for receiving hydraulic oil; and a steering block which comprises: two first hydraulic connections for connecting to the two hydraulic connections of the steering cylinder; at least two second hydraulic connections for supplying hydraulic oil from the hydraulic pump to the steering block and feeding the hydraulic oil back into the hydraulic tank; and a controllable valve assembly which receives control signals from a steering angle detection device and is designed to convey hydraulic oil to the steering cylinder on the basis of said control signals; the controllable valve assembly being further designed to be shiftable into at least one neutral position in which it allows a flow of hydraulic oil between the two chambers of the steering cylinder. The hydraulic steering system further comprises a pump device which is designed to stimulate the flow of hydraulic oil between the two chambers of the steering cylinder when the valve assembly is in the neutral position.

A materials handling vehicle includes an operator platform from which an operator can drive the vehicle; a traction control system for advancing the vehicle across a floor surface; at least one sensor configured to detect the presence of an object located at a position proximate to the vehicle; and a controller communicably coupled to the at least one sensor and the traction control system. The controller is responsive to the output of the at least one sensor to stop or slow down the vehicle if an object is detected proximate to the vehicle and the vehicle is traveling in response to a remote travel request. However, the controller does not slow down or stop the vehicle if an object is proximate to the vehicle while the operator is driving the vehicle on the operator platform.

The disclosed subject matter is directed to a hydraulic steering shear-fork aerial work platform that comprises a running chassis and a lifting device. The running chassis includes a chassis body and a running device that comprises a left wheel carrier, a right wheel carrier, a linkage frame, and a steering oil cylinder. The left wheel carrier and the right wheel carrier are rotatably installed on the chassis body through wheel carrier shafts. The two ends of the linkage frame are respectively hinged to the left wheel carrier and the right wheel carrier. One end of the steering oil cylinder is installed at one end of the linkage frame, and the other end of the steering oil cylinder is fixedly connected with the wheel carrier shaft through an installing plate.

A steering system for a vehicle includes at least two wheels configured to be steered independently of each another. A steering setpoint generator is configured to steer the at least two wheels according to a steering program. An operating element is configured to rotate the vehicle during travel about a center of rotation which moves with a principal movement vector. The steering program is configured so that a direction of the principal movement vector of the center of rotation can be changed with the steering setpoint generator.

A materials handling vehicle is provided having: a power unit comprising at least one wheel; a mast assembly coupled to the power unit comprising at least one mast weldment; and a platform assembly. The platform assembly comprising: a floorboard upon which an operator may stand; a support wall connected to the floorboard and positioned adjacent to the mast assembly, the floorboard and the support wall defining an operator compartment of the platform assembly; at least one operator control assembly positioned to allow for operation by an operator located within the operator compartment; and a non-horizontal viewing window provided in the support wall.

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.