The invention relates to a method for compensating a stick-slip effect in the case of a recirculating ball steering system (20) having a steering housing (22), in which a steering piston (24) is supported between a first working chamber (34) and a second working chamber (36), wherein the steering piston (24) has a toothed region (26) on the steering-piston outer wall of the steering position, with which toothed region teeth (28) of a segment shaft (30) mesh, the steering piston (24) can be moved along a longitudinal axis X-X, the working chambers (34, 36) are connected to a control valve (39) by means of pressure-medium lines in order to provide steering assistance, the control valve (39) is connected to a processor unit (40), by means of which valves of the control valve (39) can be actuated, and the processor unit (40) is connected to a sensor (42), which determines rotation of the steering column both in a first direction of rotation and in a second, opposite direction of rotation. When a rotational motion of the steering column in a first direction occurs and thereafter the rotational motion in said direction nearly or completely stops, the valves of the control valve (39) are opened by the processor unit (40) in such a way that the pressure in the working chamber (34, 36) of the steering piston (24) facing away from the direction of motion of the steering piston (24) is reduced and immediately thereafter the pressure in the same working chamber (34, 36) is increased again.

The invention relates to a method for compensating a stick-slip effect in the case of a recirculating ball steering system (20) having a steering housing (22), in which a steering piston (24) is supported between a first working chamber (34) and a second working chamber (36), wherein the steering piston (24) has a toothed region (26) on the steering-piston outer wall of the steering position, with which toothed region teeth (28) of a segment shaft (30) mesh, the steering piston (24) can be moved along a longitudinal axis X-X, the working chambers (34, 36) are connected to a control valve (39) by means of pressure-medium lines in order to provide steering assistance, the control valve (39) is connected to a processor unit (40), by means of which valves of the control valve (39) can be actuated, and the processor unit (40) is connected to a sensor (42), which determines rotation of the steering column both in a first direction of rotation and in a second, opposite direction of rotation. When a rotational motion of the steering column in a first direction occurs and thereafter the rotational motion in said direction nearly or completely stops, the valves of the control valve (39) are opened by the processor unit (40) in such a way that the pressure in the working chamber (34, 36) of the steering piston (24) facing away from the direction of motion of the steering piston (24) is reduced and immediately thereafter the pressure in the same working chamber (34, 36) is increased again.

A power steering assembly for an electromechanical power steering system of motor vehicles, in particular utility vehicles, includes a steering gear, the steering gear being designed to transmit a rotational movement introduced by a steering element such as a steering wheel, via an input side of the steering gear, to an output side of the steering gear. The power steering assembly converts a movement derived from the output side of the steering gear into a rotational movement of at least one wheel of the motor vehicle about a steering axis. An adjustable absorption unit is provided for at least partially absorbing roadside shocks which have been absorbed via the wheel of the motor vehicle. A separate preloading unit is designed to interact with the adjustable absorption unit such that a predetermined preloading force is exerted onto the adjustable absorption unit.

A power steering assembly for an electromechanical power steering system of motor vehicles, in particular utility vehicles, includes a steering gear, the steering gear being designed to transmit a rotational movement introduced by a steering element such as a steering wheel, via an input side of the steering gear, to an output side of the steering gear. The power steering assembly converts a movement derived from the output side of the steering gear into a rotational movement of at least one wheel of the motor vehicle about a steering axis. An adjustable absorption unit is provided for at least partially absorbing roadside shocks which have been absorbed via the wheel of the motor vehicle. A separate preloading unit is designed to interact with the adjustable absorption unit such that a predetermined preloading force is exerted onto the adjustable absorption unit.

A steering system includes: a steering shaft to which a steering member is coupled; a worm wheel attached to the steering shaft so as to be rotatable integrally with the steering shaft; a housing that houses the worm wheel; an output shaft that is coaxial with the steering shaft and rotatable relative to the steering shaft and coupled to a steering operation mechanism; and a clutch mechanism that enables and disables transmission of power between the steering shaft and the output shaft. The clutch mechanism is housed and disposed in an internal space in the housing. A solenoid in the clutch mechanism is disposed on the opposite side of the worm wheel in an axial direction from a mechanical portion of the clutch mechanism.

A steering system includes: a steering shaft to which a steering member is coupled; a worm wheel attached to the steering shaft so as to be rotatable integrally with the steering shaft; a housing that houses the worm wheel; an output shaft that is coaxial with the steering shaft and rotatable relative to the steering shaft and coupled to a steering operation mechanism; and a clutch mechanism that enables and disables transmission of power between the steering shaft and the output shaft. The clutch mechanism is housed and disposed in an internal space in the housing. A solenoid in the clutch mechanism is disposed on the opposite side of the worm wheel in an axial direction from a mechanical portion of the clutch mechanism.

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.

The present invention provides a power steering apparatus capable of realizing a reduction in an axial dimension of the apparatus. A resolver 16, which detects a rotational position of a motor rotor 13, is provided between a motor element 15 and a steering housing 6 in a direction of an x axis. A bolt 19, which fixes a motor housing 17 to the steering housing 6, is provided so as to overlap the resolver 16 in the direction of the x axis radially outside the resolver 16.

The present invention provides a power steering apparatus capable of realizing a reduction in an axial dimension of the apparatus. A resolver 16, which detects a rotational position of a motor rotor 13, is provided between a motor element 15 and a steering housing 6 in a direction of an x axis. A bolt 19, which fixes a motor housing 17 to the steering housing 6, is provided so as to overlap the resolver 16 in the direction of the x axis radially outside the resolver 16.

In a steering device (PS1) according to the present embodiment, a preload applying mechanism (6) provides a rotation torque to one side in a rotation direction of a ball nut (4) by a reaction force generated by elastic abutment of a plunger (61) on a tooth tip of a first sector tooth (321) of a sector gear (32). Therefore, in the steering device (PS1), unlike conventional steering device, there is no need to provide a pressed portion to be pressed by the plunger (61) separately from the sector gear (32). Increase in size of a sector shaft (3) due to formation of the pressed portion can therefore be suppressed.