An overload suspension system configured for operative engagement to a vehicle having a first leaf spring and second leaf spring to provide auxiliary support to the vehicle when overloaded. A first control arm attached to a first torsion bar has a distal end positioned a separation distance from the first leaf spring. A second control arm attached to the second control arm has a distal end positioned substantially the same separation distance from the second leaf spring. The suspension system operates as an auxiliary suspension only when added weight to the vehicle deflects both leaf springs to contact a respective one of the control arms, thereby preserving the ride and suspension characteristics of the vehicle when the added weight is not present.

A rotary cutter having a torsional suspension system may include a main frame, a deck supported by the frame, at least one rotary cutter mounted to the deck, at least one wheel, and a torsional suspension system connecting the at least one wheel to the frame. The torsional suspension system may include an outer tubular housing, an inner torsional tube disposed in the outer housing and configured to form cavities between the outer housing and the inner torsional tube, and elastomeric cords disposed in the cavities and configured for providing torsional resistance to rotation of the outer housing relative to the inner torsional tube.

A suspension structure for an in-wheel motor drive device of the present invention includes an in-wheel motor drive device (10), a shock absorber (76), a torsion bar (81), and a stabilizer link (86), wherein: the shock absorber includes an upper spring seat (79a) provided in an upper end region of the shock absorber and a lower spring seat (79b) provided in a lower end region of the shock absorber and forming a pair with the upper spring seat; an upper end (87a) of the stabilizer link is arranged between a vehicle back edge (79d) of the lower spring seat and a vehicle front edge (79c) of the lower spring seat; and a lower end (87b) of the stabilizer link is arranged so as to overlap with a hub wheel (12) as viewed in an axial direction of the hub wheel.

The twist axle assembly includes a pair of spaced apart trailing arms and a twist beam of which extends in a first direction between the trailing arms. The twist beam includes a pair of end portions and a middle portion. The twist beam further has a pair of side walls and at least one additional wall that extends between the side walls. The side walls in the middle portion are generally parallel with the side walls of the end portions. The twist beam is generally hour-glass shaped with the middle portion having a first width and the end portions have a greater second width. The twist beam also tapers from the first width of the middle portion to the second widths of the end portions for gradually increasing a torsional stiffness from the middle portion to the end portions.

The present invention relates to a suspension arrangement for a tracked vehicle. The suspension arrangement includes a road wheel arm having a wheel axle portion for supporting a wheel of the vehicle and a pivot axle portion. The road wheel arm is pivotably journalled at the pivot axle portion to a housing that is fixable to the vehicle body. A torsion bar is connected to the pivot axle portion and a torsion tube is arranged to be connected to the vehicle body, with the torsion bar running through the torsion tube and arranged to be connected to the torsion tube. The modulus of elasticity of the torsion tube material is lower than the modulus of elasticity of the torsion bar material such that the maximum suspension travel is increased.

The present inventions relate to structural components of vehicles, and more particularly to suspension variants of both usual cars and special higher comfort vehicles, such as ambulances, baby carriages and wheelchairs, and also the suspension with catamaran floats. The proposed suspension, which may be used in ground and water vehicles, is configured to enable automatic road clearance and body tilt adjustment depending on the condition of the roadway, sea roughness, the speed of the vehicle and the maneuver being performed. The first variant of suspension comprises a frame, four identical arms intended to be connected with the hubs of the respective motion parts, and torsion bars attached to the frame through the bearing assemblies and connected to the arms of the corresponding motion parts, where at least two torsion bars may freely rotate with a twisting angle under the load of 1-5 and form, respectively, front and rear axis, the torsion bars are installed in parallel and their centers are kinematically connected to a connecting rod mounted in such a manner to allow synchronous axial rotation of the torsion bars, the arms of one axis are attached to the ends of the corresponding torsion bars and are installed in parallel, while the arms of each side of the suspension, i.e. right or left, are oriented in opposite directions, wherein the suspension according to the invention comprises at least four torsion bars disposed in pairs in a horizontal plane, and, additionally, the main and additional movable connection arms and linear actuators that are mounted in such a manner to allow synchronous change of their lengths, while the center of each torsion bar is connected to the connecting rod via an additional connection arm, which can freely rotate on the torsion bar, all additional connection arms are parallel, identically oriented and connected with each other by appropriate rods, and the arms of the corresponding motion parts of one axis are attached to the ends of the corresponding torsion bars, installed in parallel and oriented in opposite directions towards each other. The second variant of suspension comprises a horizontally disposed frame, a steering mechanism, four identical wheel arms, each intended to be connected at one end to the hub of the corresponding wheel, and to be connected at the other end, through a bearing assembly attached to the frame, to a coupling device installed with the possibility of its free rotation, and the coupling devices form, respectively, front and rear suspension axles, the axes of the coupling devices of both axles are installed in parallel and the arms of the wheels of one axle are installed in parallel, wherein acco

An axle cartridge member receives a pair of torsion stub axles at opposite lateral sides thereof. The torsion stub axles include elongated axle housings, which are sandwiched between two parallel plates to align the torsion stub axles with respect to one another. The cartridge member includes a central arch extending between the two torsion stub axles, which can provide additional ground clearance when the axle cartridge member is mounted to a trailer.

A stabilizer includes a stabilizer main body, and eyes formed on both ends of the stabilizer main body. Through-holes are formed in fastening surfaces of the eyes, respectively. The stabilizer main body is covered with a main body coating film. The eye is covered with an eye coating film whose thickness is less than a thickness of the main body coating film. An inner surface of the through-hole is covered with an inner surface coating film. An incomplete coating portion is formed at a part of the inner surface of the through-hole in a circumferential direction. The incomplete coating portion is located on an extension of a straight line connecting a center of the through-hole and the center of gravity of the stabilizer main body in a side view of the stabilizer main body.

A dual rate torsion bar suspension system is connected to a control arm and includes a first rate torsion bar and a second rate torsion bar connected to one another in order to provide the suspension system with a dual rate torque resistance. A cam mechanism is employed for isolating the second rate torsion bar from the first rate torsion bar.

A dual rate torsion bar suspension system is connected to a control arm and includes a first rate torsion bar and a second rate torsion bar connected to one another in order to provide the suspension system with a dual rate torque resistance. A cam mechanism is employed for isolating the second rate torsion bar from the first rate torsion bar.