A single axle suspension system including right and left dampers, first and second hydraulic circuits, a first pressurizing mechanism connected in fluid communication with the first and second hydraulic circuits, and a second pressurizing mechanism connected in series with the first pressurizing mechanism. The first pressurizing mechanism provides roll control by generating a pressure differential between the first and second hydraulic circuits. This causes an increase in the fluid pressure inside either the first working chamber of the right damper and the second working chamber of the left damper or inside the first working chamber of the left damper and the second working chambers of the right damper to provide roll stiffness that counters vehicle roll during cornering. The second pressurizing mechanism adjusts static pressure within the first and second hydraulic circuits by adding and removing hydraulic fluid to and from the first and second hydraulic circuits.

A single axle suspension system including right and left dampers, first and second hydraulic circuits, a first pressurizing mechanism connected in fluid communication with the first and second hydraulic circuits, and a second pressurizing mechanism connected in series with the first pressurizing mechanism. The first pressurizing mechanism is a gerotor pump that provides roll control by generating a pressure differential between the first and second hydraulic circuits, which increases fluid pressure inside either the first working chamber of the right damper and the second working chamber of the left damper or inside the first working chamber of the left damper and the second working chambers of the right damper to provide roll stiffness that counters vehicle roll during cornering. The second pressurizing mechanism adjusts static pressure within the first and second hydraulic circuits by adding and removing hydraulic fluid to and from the first and second hydraulic circuits.

A stabilizer includes a stabilizer bar, left and right cylinders, a parallel pipe, a cross pipe, a parallel on-off valve, and a valve controller. The parallel on-off valve maintains communication between a left side first fluid room of the left cylinder and a right side first fluid room of the right cylinder and maintains communication between a left side second fluid room of the left cylinder and a right side second fluid room of the right cylinder by opening itself. The parallel on-off valve cuts off the communication by closing itself. The valve controller switches an opening/closing state of the parallel on-off valve based on a running state of a vehicle or an operation state of the vehicle by a driver.

Aspects of the present disclosure relate to a locking control method for a pivot axle of a wheeled working machine including: determining, using a multibody simulation model, a current posture and motion state of the working machine and static and dynamic forces acting on the working machine; determining a relevant tipping line based on a current locking status of a pivot axle of the working machine; calculating torques acting on the working machine based on the information on current posture, motion state, static and dynamic forces; determining a control command for a pivot axle locking mechanism of the working machine based on the calculated torques and the tipping line; and providing the control command to a pivot axle locking mechanism.

Methods, apparatus, systems, and articles of manufacture to determine the load of a vehicle via calibrate a suspension sensor are disclosed herein. An example vehicle described herein includes a force transducer, an actuator coupled to the force transducer, memory including instructions and a processor to execute the instructions to engage the actuator to a bottom surface of a vehicle, apply a first force to the bottom surface via the actuator, determine a first displacement of a first suspension component of the vehicle, and calibrate a first sensor of the vehicle based on the first force and the first displacement.

Aspects of the present invention relate to a control system (100, 200) for a vehicle suspension system of a vehicle (800). The control system is configured to perform a test for testing operation of an isolation switch (430). The vehicle suspension system comprises an actuator power supply (450) configured to supply power to the vehicle suspension system. The actuator power supply is configured to be electrically connected to the vehicle suspension system via the isolation switch. The control system is configured to: receive a shutdown indicator signal indicating that the vehicle is in a shutdown state (530); output an open isolation switch signal (524) configured to open the isolation switch in dependence on the shutdown indicator signal; receive an open isolation switch confirmation signal (516) indicative of the isolation switch being open; determine whether the open isolation switch confirmation signal is received within a predetermined time period; and output a test pass signal or a test failure signal in dependence on the determination.

A roll control system for a vehicle capable of improving the versatility compared to the related art is obtained. A roll control system according to the invention includes: a first component connected to a right connecting device that connects a vehicle body and a right wheel; a second component connected to a left connecting device that connects the vehicle body and a left wheel; and a damper. The damper includes a first damper component and a second damper component reciprocatably connected to each other. The first component includes a first base portion rotatably held by the vehicle body, a first wheel-side arm portion rotatably connected to the right connecting device, and a first damper-side arm portion rotatably connected to the first damper component. The second component includes a second base portion rotatably held by the vehicle body, a second wheel-side arm portion rotatably connected to the left connecting device, and a second damper-side arm portion rotatably connected to the second damper component.

A method for alleviating the consequences of a collision of a vehicle, having a front axle and/or a rear axle with at least one roll stabilization device with which torques can be applied in the region of the front axle and/or the rear axle for the purpose of roll stabilization. In order to alleviate the consequences of collisions of vehicles, in the event of a collision protective torques are generated using the roll stabilization devices.

A system and method for operating a motor vehicle having an active roll control system and an air suspension system including operating the air suspension system in a normal mode, according to a normal air spring setting. Upon determining a fault or malfunction of the active roll control system operating the air suspension in a fallback mode, according to a fallback air spring setting, wherein the fallback mode is different from the normal mode.

An adjustment system and method for adjusting a chassis property of a motor vehicle wherein an understeering sensitivity of the motor vehicle is increased upon detecting that a trailer has been coupled to the motor vehicle. A detection unit operates to detect when a trailer is attached or coupled to the motor vehicle.