A cantilever bushing assembly anchors the central torsional section of a vehicular stabilizer bar in a cantilevered manner relative to a vehicle understructure. The bushing assembly comprises a bracket having a pocket centered on a pocket axis that coincides with a longitudinal axis of the stabilizer bar. Two plastic outer cans are cooperatively slidable into the pocket. Each outer can has an anti-rotation lobe received in respective keyways formed in the pocket. A rubber buffer is bonded to each outer can. Each rubber buffer has a frusto-cylindrical inner bearing surface that forms an arcuate portion of an interior bushing diameter. The inner bearing surface is post-vulcanization bonded to the central torsional section of the stabilizer bar. An arched rate plate is embedded within each rubber buffer. The rubber buffers compress in the area of the inner bearing surfaces and constrict about the central torsional section of the stabilizer bar.

A vehicle suspension is disclosed having a hydraulic actuator, a cylinder, a piston mounted inside the cylinder dividing the cylinder into a compression chamber and an extension chamber, and a supply hydraulic circuit connected to the actuator to supply the compression chamber and the extension chamber with working fluid. The supply hydraulic circuit includes a high-pressure line connected to a delivery port of a hydraulic pump, a low-pressure line connected to a suction port of the pump, a spool valve connected to the compression and extension chambers of the actuator and to the high-pressure line and to the low-pressure line to put the chambers of the actuator in communication with the lines of the supply hydraulic circuit, and a first pressure accumulator connected to the high-pressure line . The spool valve connects the compression chamber and/or the extension chamber of the actuator with the high-pressure line.

A suspension system including four dampers is disclosed where each damper includes a compression chamber and a rebound chamber. A first hydraulic circuit includes a front hydraulic line, a rear hydraulic line, and a first longitudinal hydraulic line that extends between and fluidly connects the front and rear hydraulic lines of the first hydraulic circuit. A second hydraulic circuit includes a front hydraulic line, a rear hydraulic line, and a second longitudinal hydraulic line that extends between and fluidly connects the front and rear hydraulic lines of the second hydraulic circuit. First and second longitudinal comfort valves are positioned in the first and second longitudinal hydraulic lines, respectively, between the front and rear hydraulic lines. Both of the first and second longitudinal comfort valves are electromechanical valves and can be actuated to couple and decouple front axle roll control from rear axle roll control.

A milling machine may have a frame, a milling drum attached to the frame, and ground engaging tracks that support the frame and propel the milling machine in a forward or rearward direction. The milling machine may have height adjustable actuators connecting the frame to the tracks. Each actuator may have a cylinder attached to the frame, a piston slidably disposed within the cylinder, and a rod connected at a first end to the piston and connected to a track at a second end. The milling machine may have a tank storing hydraulic fluid and a fluid conduit connecting the tank to the cylinder. The milling machine may have a control valve selectively controlling a flow rate of the hydraulic fluid in the fluid conduit. The milling machine may also have a controller that determines a height of the frame relative to the ground surface based on the flow rate.

A vehicle includes a suspension system having a first damper, a second damper, and a controller. The dampers include housings and pistons sealingly interfaced with an inner diameter of the housing, dividing the damper into a first and second chamber. The suspension system includes proportional variable relief valves which control pressure of fluid entering or exiting one of the first and second chamber of one of the first and second damper. The controller controls the valves to control extension or compression of the first damper and extension or compression of the second damper based on a degree of roll of the vehicle during a turn of the vehicle or a degree of pitch of the vehicle during acceleration or deceleration of the vehicle. The first and second damper control a roll and pitch of the vehicle. The valves control a damping rate of one of the first and second damper.

A suspension assembly for a vehicle may include a first stabilizer bar operably coupled to a first wheel on a first side of the vehicle, a second stabilizer bar operably coupled to a second wheel on a second side of the vehicle, and an chassis coupler comprising an inverter housing and an actuator assembly. The actuator assembly may be operable to arrange the first stabilizer bar and the second stabilizer bar in a selected one of a connected state, a disconnected state, and an inverted state. The inverter housing may be alternately constrained to one of the first stabilizer bar or the chassis coupler based on a position of the actuator assembly to define each of the connected state, the disconnected state and the inverted state.

A vehicle includes a suspension system having a first damper, a second damper, valves and a controller. Each of the first damper and the second damper include a housing and a piston sealingly interfaced with an inner diameter of the housing, dividing the damper into a first and second chamber. Each valve controls flow rate of fluid entering or exiting at least one of the first and second chamber of at least one of the first damper and the second damper. The controller controls the valves to control extension or compression of at least one of the first damper and the second damper based on at least one of a degree of roll of the vehicle during a turn of the vehicle and a degree of pitch of the vehicle during acceleration of the vehicle or a degree of pitch of the vehicle during deceleration of the vehicle.

An control device for an oscillating axle suspension, in particular a front axle suspension, consisting at least of one hydraulic accumulator device (10), a suspension device (12) and a proportional valve (14) having a valve piston (26), wherein to said proportional valve (14) the two devices (10, 12) are connected via fluid ports (16, 18, 20, 22), is characterized in that the valve piston (26), actuatable by an electric motor (28), is longitudinally guided in a valve housing (24) of the proportional valve (14) and controls the fluid ports (16, 18, 20, 22) such that, in at least one functional position (1) of the valve piston (26), the axle oscillation is provided while the suspension is blocked and, in at least one further second functional position (2) of the valve piston (26), the suspension is provided while the axle oscillation is blocked.

A cantilever bushing assembly anchors the central torsional section of a vehicular stabilizer bar in a cantilevered manner relative to a vehicle understructure. The bushing assembly comprises a bracket having a pocket centered on a pocket axis that coincides with a longitudinal axis of the stabilizer bar. Two plastic outer cans are cooperatively slidable into the pocket. Each outer can has an anti-rotation lobe received in respective keyways formed in the pocket. A rubber buffer is bonded to each outer can. Each rubber buffer has a frusto-cylindrical inner bearing surface that forms an arcuate portion of an interior bushing diameter. The inner bearing surface is post-vulcanization bonded to the central torsional section of the stabilizer bar. An arched rate plate is embedded within each rubber buffer. The rubber buffers compress in the area of the inner bearing surfaces and constrict about the central torsional section of the stabilizer bar.

An assembly system for components of a pressurized fluid supply system for an agricultural vehicle includes a body having at least one fluid duct connectable at one end to a pressurized fluid supply and having a socket at the other end. A detachable component such as an accumulator or oil filter is connectable in releasable mechanical engagement with the body to receive pressurized fluid from the at least one fluid duct. The engagement results from insertion of at least a portion of the component into the socket and rotation of the component to a locked position. The body has at least one discharge duct extending therethrough. In a partially rotated position of the component portion within the socket, the component remains mechanically attached to the body and the fluid duct and discharge duct are in fluidic connection, discharging accumulated pressure in the fluid duct.