Integrated multiple actuator electro-hydraulic systems as well as their methods of use are described. Depending on the particular application, the integrated electro-hydraulic systems may exhibit different frequency responses and/or may be integrated into a single combined unit.

A hydraulic level-adjustment device has a reservoir, a reversible hydraulic unit with a hydraulic pump, and a single-acting hydraulic linear actuator. To lift a vehicle chassis, the working space of the linear actuator can be pressurized by the hydraulic pump operated in its first pumping direction via its first pump connection and a fill line with a fill-check valve arranged therein. To lower the chassis, via its second pump connection, the hydraulic pump, operated in the reverse pumping direction, pumps hydraulic fluid into the reservoir via an outflow line with a throttle unit arranged therein. The pressure present upstream of the throttle unit acts on the control connection of a lockable, drainage-check valve via a control line and opens same, so that, under the weight of the motor vehicle, hydraulic fluid is forced out of the working space of the hydraulic linear actuator into the reservoir via the drainage line.

The disclosure relates to a leveling system useful for self-leveling casters on suspension systems of harvesters, such as self-propelled windrowers. The suspension system utilizes position sensors and hydraulic actuators operably linked to each caster, the hydraulic actuators responding to a rotational position of the caster as detected by the respective position sensor to level the caster.

A vehicle height control system includes a fluid feeder and a vehicle height control unit. The vehicle height control unit includes a communication control unit. In a first communication state, a high-pressure source and a common passage are made to communicate with each other via the first passage and the second passage. In a second communication state, the first passage is shut off and the high-pressure source and the common passage are made to communicate with each other via the second passage. The communication control unit selects one from among the plurality of communication states based on at least one of a content of a start condition, a target vehicle height of a height increasing control and a number of wheels to be controlled in the height increasing control, when the start condition of the height increasing control is satisfied.

A hydraulic system for the preferably active damping control of a motor vehicle. The system includes at least one damper, with which a damper shutoff member is associated and to which at least one hydraulic line is hydraulically connected. In order to simplify the assembly of the hydraulic damper, an end of the hydraulic line facing the damper is equipped with a line shutoff member, wherein the line shutoff member at the end of the hydraulic line facing the damper is integrated into a line connection block, which is secured in a hydraulically sealed but releasable manner to a damper connection block by the damper shutoff member being merged, along with a filling member, into a combined filling valve which is integrated into the damper connection block.

The disclosure relates to a leveling system useful for self-leveling casters on suspension systems of harvesters, such as self-propelled windrowers. The suspension system utilizes position sensors and hydraulic actuators operably linked to each caster, the hydraulic actuators responding to a rotational position of the caster as detected by the respective position sensor to level the caster.

A suspension system including hydraulic circuits that extend between dampers located at opposite corners of the vehicle and at least one load distribution unit that is connected in fluid communication with at least two hydraulic circuits. The load distribution unit includes a manifold block with a cylinder bore, a pair of pressure tubes, a piston rod assembly, and a pair of reserve tubes. The pressure tubes are partially received in the cylinder bore to define a pair of opposed cylinders. The piston rod assembly includes a piston rod and a pair of opposed pistons that are slidingly received within the opposed cylinders. The reserve tubes are at least partially received in the cylinder bore and are arranged annularly about the pressure tubes to define a first pair of reservoir chambers between the pressure tubes and the reserve tubes.

There is provided a railway vehicle vibration control apparatus that can reduce the amount of power consumed. A railway vehicle vibration control apparatus (1) of the present invention includes a first semi-active damper (D1) that functions as a semi-active damper under normal control and enters an unloaded state upon non-energization, and a second semi-active damper (D2) that functions as a semi-active damper under normal control and as a passive damper in a non-energized state or an actuator (A) that functions as an actuator under normal control and as a passive damper in the non-energized state.

A vehicle and a height adjustment system for the vehicle are disclosed. A valve includes a member movable between a first position operating first and second piston mechanisms to raise an end of the vehicle to a first height, a second position operating the first and second piston mechanisms to lower the end of the vehicle to a second height and a third position maintaining the end of the vehicle at one of the first height and the second height. A first fluid line extends between the first piston mechanism and the valve to fluidly connect the first piston mechanism and the valve. Additionally, a second fluid line extends between the second piston mechanism and the valve to fluidly connect the second piston mechanism and the valve. The first fluid line and the second fluid line are fluidly connected to the valve independently of each other.

A flow-through hydraulic valve slide (14a-b), in particular for a control valve (10a-b) for regulating damping characteristics of shock absorbers, has at least one hydraulic link valve (12a-b) for influencing a flow-through of the valve slide (14a-b), wherein the hydraulic link valve (12a-b) comprises at least one first control port (16a-b), at least one second control port (18a-b), at least one entry (20a-b, 36a-b) and at least one exit (22a-b, 40b) which can be opened in an interchangeable manner at least towards the entry (20a-b).