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.

A steering assembly system is provided having a steering actuator comprising a double rod end cylinder having: a cylinder barrel having a length, a first end with a first cap, and a second end with a second cap, and a first, second and third fluid port, each respectively in fluid communication with a first, second, and third chamber; a piston rod having a first rod end and a second rod end with a length extending therebetween, and the first rod end extending through the first cap and the second rod end extending through the second cap of the cylinder barrel; a first piston having a first dimension and mechanically secured at a point along the length of the main piston rod; a second piston having a second dimension larger than the first dimension of the first piston, and main piston rod extending through at least the length of the barrel.

A steering assembly system is provided having a steering actuator comprising a double rod end cylinder having: a cylinder barrel having a length, a first end with a first cap, and a second end with a second cap, and a first, second and third fluid port, each respectively in fluid communication with a first, second, and third chamber; a piston rod having a first rod end and a second rod end with a length extending therebetween, and the first rod end extending through the first cap and the second rod end extending through the second cap of the cylinder barrel; a first piston having a first dimension and mechanically secured at a point along the length of the main piston rod; a second piston having a second dimension larger than the first dimension of the first piston, and main piston rod extending through at least the length of the barrel.

Hydraulic steering (1) is disclosed comprising a high pressure port (P), a low pressure port (T), two working ports (CL, CR), a manual steering section (3), and a steering valve section having a steering valve 5 and a hydraulic driving arrangement (6) adjusting hydraulically a position of said steering valve. A change from automatic steering to manual steering should be reliably ensured when the manual steering section is directly influenced by a driver. To this end, a switching valve (11) is provided, which is actuatable between a first position in which said driving arrangement (6) is supplied with hydraulic fluid under pressure, and a second position in which a supply of hydraulic fluid to said driving arrangement (6) is interrupted, wherein said switching valve (11) is hydraulically actuated into said second position by a pressure generated upon actuating of said manual steering section (3).

Hydraulic steering (1) is disclosed comprising a high pressure port (P), a low pressure port (T), two working ports (CL, CR), a manual steering section (3), and a steering valve section having a steering valve 5 and a hydraulic driving arrangement (6) adjusting hydraulically a position of said steering valve. A change from automatic steering to manual steering should be reliably ensured when the manual steering section is directly influenced by a driver. To this end, a switching valve (11) is provided, which is actuatable between a first position in which said driving arrangement (6) is supplied with hydraulic fluid under pressure, and a second position in which a supply of hydraulic fluid to said driving arrangement (6) is interrupted, wherein said switching valve (11) is hydraulically actuated into said second position by a pressure generated upon actuating of said manual steering section (3).

A hydraulic steering system for vehicles includes a steering control member; a hydraulic pump provided with a rotatable driving shaft on which the control member is fitted; a hydraulic actuating cylinder connected with two ports of the pump alternately operating as delivery side and return side of the pump and mechanically connected with a direction changing member, which determines a change in the direction by modifying orientation via an actuating cylinder as a function of the supply of hydraulic fluid to the cylinder from the pump by the steering control member. The driving shaft is dynamically connected with an electric motor/transmission assembly, which is activated alternatively by generating a rotational force auxiliary to the movement manually exerted on the steering control member or opposing the manually exerted movement, or by driving to rotate the driving shaft of the pump in place of the manual action driving the steering control member.

A steering system for an agricultural vehicle has at least one steering cylinder for changing a steering angle of the agricultural vehicle, a hydraulic main steering valve for pressurizing the at least one steering cylinder, a steering transducer for actuating the main steering valve, a steering boost for controlling an adjustment characteristic between the steering transducer and the at least one steering cylinder and a sensor system for detecting an external signal of the agricultural vehicle. The steering boost controls the adjustment characteristic on the basis of the detected external signal.

A steering system for an agricultural vehicle has at least one steering cylinder for changing a steering angle of the agricultural vehicle, a hydraulic main steering valve for pressurizing the at least one steering cylinder, a steering transducer for actuating the main steering valve, a steering boost for controlling an adjustment characteristic between the steering transducer and the at least one steering cylinder and a sensor system for detecting an external signal of the agricultural vehicle. The steering boost controls the adjustment characteristic on the basis of the detected external signal.

A fluid connector for connecting fluid conduit to a component in the presence of an electrolyte solution includes a connector body and sacrificial anode. The connector body defines an internal recess. The sacrificial anode can be press-fitted into the internal recess and circumscribed by the connector body. The sacrificial anode, which is constructed of a material that is configured to be consumed over a life of the component to prevent or delay corrosion of the connector body due to contact with the electrolyte solution, may be constructed of aluminum, magnesium, zinc, or other active metals. A fluid system for use in the presence of the electrolyte solution includes the component, fluid conduit, a pump, and the fluid connector. A vehicle includes the fluid system and a vehicle body. The component may be a steering gear assembly in some embodiments.