A wheel load adjusting apparatus used in a railcar, and the railcar includes: first and second air springs arranged between a carbody and a first bogie so as to be spaced apart from each other in a car width direction; third and fourth air springs arranged between the carbody and a second bogie so as to be spaced apart from each other in the car width direction; and first to fourth automatic level controlling valves provided upstream of the first four air springs and configured to adjust heights of the four air springs to maintain constant height of the air springs, wherein when the railcar passes through a curve, the wheel load adjusting apparatus limits an air supply/air discharge operation of at least one of the four automatic level controlling valves to suppress an increase in a pressure difference between at least two of the four air springs.

A control system for a work vehicle, includes a controller. The controller includes a processor a memory device communicatively coupled to the processor, such that the memory device stores instructions that cause the processor to receive a first control signal indicative of performing relocation operations. Furthermore, the instructions cause the processor to instruct an actuator assembly to drive a chassis of the work vehicle in an upward direction relative to wheels of the work vehicle in response to receiving the first control signal, such that a front stabilizer and a rear stabilizer are disengaged from a ground.

One or more vehicle sensors can be used in a suspension control system of an agricultural machine to dynamically adjust pistons located proximal to wheels of the machine to substantially control orientation. Such vehicle sensors could include: a speed sensor configured to provide an output indicating a speed of the machine; a turn angle sensor configured to provide an output indicating a turn angle of the machine; and/or an Inertial Measurement Unit (IMU) configured to detect a chassis-to-horizon angle. The output can be compared to a threshold for determining when to control valves in the suspension system to apply height corrections.

A suspension device includes an actuator device provided with an extensible/contractible actuator body interposed between a sprung member and an unsprung member of a vehicle, a pump that supplies fluid to the actuator body to extend or contract the actuator body, and a controller that controls a rotation number of the pump. The controller has a road surface state index obtainment unit that obtains a road surface state index and a target rotation number determination unit that determines a target rotation number of the pump on the basis of the road surface state index.

A vehicle suspension system may include hydraulic actuators, first and second conduits, and first and second switch valves. Each actuator includes a cylinder and a piston that divides an interior of the cylinder into compression and rebound chambers. First and third ports of each cylinder are openings to the rebound chamber. Second and fourth ports of each cylinder are openings to the compression chamber. The first conduit connects the third port of a first actuator with the fourth port of a second actuator. The second conduit fluidly connects the third port of the second actuator with the fourth port of the first actuator. The first switch valve is connected to the first and second ports of the first one of the hydraulic actuators. The second switch valve is connected to the first and second ports of the second one of the hydraulic actuators.

A vehicle suspension system may include hydraulic actuators, first and second conduits, and first and second switch valves. Each actuator includes a cylinder and a piston that divides an interior of the cylinder into compression and rebound chambers. First and third ports of each cylinder are openings to the rebound chamber. Second and fourth ports of each cylinder are openings to the compression chamber. The first conduit connects the third port of a first actuator with the fourth port of a second actuator. The second conduit fluidly connects the third port of the second actuator with the fourth port of the first actuator. The first switch valve is connected to the first and second ports of the first one of the hydraulic actuators. The second switch valve is connected to the first and second ports of the second one of the hydraulic actuators.

A spring strut for a vehicle suspension system includes a spring cylinder defining a cylinder chamber and a spring piston longitudinally displaceable in the spring cylinder. The spring piston subdivides the cylinder chamber into a first and a second outer working chamber. The spring cylinder includes an inner plunger which subdivides a piston chamber formed by the spring piston into a first and a second inner working chamber. The first inner working chamber is simultaneously formed by subdividing the cylinder chamber by means of the spring piston.

A load distribution apparatus of magnetic wheel, includes: a plurality of cylinder parts including one sides respectively connected to a plurality of magnetic wheels and an upper space portion and a lower space portion whose interiors do not communicate to each other; and a passage part which serves as a moving path of fluid and interconnects the plurality of cylinder parts. The passage part is configured to evenly distribute a load applied to the magnetic wheels by moving fluids in the upper space portion and the lower space portion in such a manner that the fluids are not mixed.

A suspension system includes a hydraulic cylinder having a piston chamber in which a piston moves and a rod chamber in which a rod moves. The hydraulic cylinder operably moves between a retraction and an extension. The system also includes a throttle valve, a branching, and a hydraulic reservoir fluidly coupled to the hydraulic cylinder. A fluid flow from the piston chamber is divided at the branching into a first fluid flow portion and a second fluid flow portion. The first fluid flow portion flows to the rod chamber of the hydraulic cylinder, and the second fluid flow portion flows through the throttle valve to the hydraulic reservoir.

A wheel suspension unit is disclosed. The wheel suspension unit includes a stabilizer having a first end and a second end, a wheel suspension element, and a piston-cylinder unit. The piston-cylinder unit connects an end of the stabilizer to the wheel suspension element. The piston-cylinder unit is a roll damper. The roll damper includes a plurality of roll damping valves arranged in a piston of the roll damper. Each of the plurality of roll damping valves has a non-return valve and an adjustable throttle valve. The non-return valve is arranged in series with the adjustable throttle valve.