In an example embodiment, a vehicle control system includes a memory including computer-readable instructions stored therein and a processor. The processor configured to execute the computer-readable instructions to receive information corresponding to, a yaw rate of a vehicle, a lateral position of the vehicle and a heading angle of the vehicle, determine a stability indicator indicating an estimate of a stability of the vehicle based on the received information, and adjust one or more gains of a steering system of the vehicle based on the determined stability indicator.

In an example embodiment, a vehicle control system includes a memory including computer-readable instructions stored therein and a processor. The processor configured to execute the computer-readable instructions to receive information corresponding to, a yaw rate of a vehicle, a lateral position of the vehicle and a heading angle of the vehicle, determine a stability indicator indicating an estimate of a stability of the vehicle based on the received information, and adjust one or more gains of a steering system of the vehicle based on the determined stability indicator.

Hydraulic bi-directional flow switches are disclosed. A disclosed example apparatus includes a piston disposed in a fluid channel between a first fluid connection and a second fluid connection, where the first and second fluid connections define a fluid pathway for hydraulic steering fluid. The example apparatus also includes a detector to detect a movement of the piston away from a default position of the piston, where the piston is to displace from the default position when the hydraulic steering fluid flows along the fluid pathway.

Hydraulic bi-directional flow switches are disclosed. A disclosed example apparatus includes a piston disposed in a fluid channel between a first fluid connection and a second fluid connection, where the first and second fluid connections define a fluid pathway for hydraulic steering fluid. The example apparatus also includes a detector to detect a movement of the piston away from a default position of the piston, where the piston is to displace from the default position when the hydraulic steering fluid flows along the fluid pathway.

An operation mode of a first actuator engaged with a steering rack is determined. An operation mode of a second actuator engaged with a steering column is determined. The operation mode of one of the first and second actuators is adjusted upon detecting a failure in the other of the first and second actuators. At least one of the steering rack and the steering column is actuated based on the operation mode. In an angle control mode, a predetermined steering angle is provided to the first and second actuators to adjust the steering rack according to the steering angle. In a torque control mode, a steering column torque from a torsion sensor disposed on the steering column is provided to the first and second actuators to adjust the steering rack according to the steering column torque.

A steering device of a working vehicle includes a lever, a first switch, a lever support member, a second switch, and a control device. The first switch sets a steering signal to be in a valid/invalid state. The lever support member is provided so as to be able to flip up from a certain position of performing tilting operation. The second switch attains conduction when the lever support member is located at the certain position, and attains non-conduction in conjunction with the case where the lever support member is flipped up. The control device sets steering with use of the lever to be valid/invalid. The first switch has a plurality of terminals which respectively attain conduction of a steering signal in accordance with a setting of a valid state and an invalid state and are electrically connected to the control device in parallel with the second switch.

A steering device of a working vehicle includes a lever, a first switch, a lever support member, a second switch, and a control device. The first switch sets a steering signal to be in a valid/invalid state. The lever support member is provided so as to be able to flip up from a certain position of performing tilting operation. The second switch attains conduction when the lever support member is located at the certain position, and attains non-conduction in conjunction with the case where the lever support member is flipped up. The control device sets steering with use of the lever to be valid/invalid. The first switch has a plurality of terminals which respectively attain conduction of a steering signal in accordance with a setting of a valid state and an invalid state and are electrically connected to the control device in parallel with the second switch.

A hydraulic drive arrangement (1) for the pressure supply of a hydraulic steering system (20), particularly for construction or agricultural machines, including a hydraulic pump (2) and an electric drive. It is essential that the electric drive is designed in a redundant fashion and has two separately controlled electric drive engines (3a, 3b), which are mechanically coupled via the hydraulic pump (2) in a rigid fashion, and that the separate control circuits (6a, 6b, 7a, 7b) are provided by which a variable load distribution can be specified for the electric drive engines (3a, 3b).

A hydraulic drive arrangement (1) for the pressure supply of a hydraulic steering system (20), particularly for construction or agricultural machines, including a hydraulic pump (2) and an electric drive. It is essential that the electric drive is designed in a redundant fashion and has two separately controlled electric drive engines (3a, 3b), which are mechanically coupled via the hydraulic pump (2) in a rigid fashion, and that the separate control circuits (6a, 6b, 7a, 7b) are provided by which a variable load distribution can be specified for the electric drive engines (3a, 3b).

An integrated clutch steering mechanism for an autonomous vehicle (AV) can include a steering clutch coupled to a steering column of the AV, and an AV steering motor coupled to the steering clutch. The AV steering motor can apply torque to the steering column via the steering clutch to control steering of the AV. When a predetermined amount of torque is exceeded on the steering column, the steering clutch slips to enable manual steering of the AV.