A vehicular dust cover assembly including: an upper support; a bound stopper and a dust cover assembled to the upper support; and an engaging step provided on an outer circumferential surface of the bound stopper. A top end part of the dust cover is externally fit to a top end part of the bound stopper. The upper support includes an outer metal fitting having a fitting recess within which the top end part of the bound stopper is fit and assembled. An engaging projection is provided projecting on an inner surface of the fitting recess to be engaged with the engaging step with the dust cover interposed therebetween. The bound stopper includes an axial pushing operation surface exposed facing axially downward which is provided at a lower side than the engaging step and at a position inside the fitting recess.

A modular low-floor transport system comprises at least one drive module and at least one carrier module. The drive module includes a drive base and a drive chassis connected to the drive base. The drive chassis includes at least one driven wheel coupled to a drive. The carrier module includes a carrier base and a carrier chassis connected to the carrier base. The carrier chassis includes at least one non-driven carrier wheel. The drive base and the carrier base are rigidly connected to each other with respect to a stroke direction, and the drive chassis is movably mounted in the stroke direction to the drive base.

An axle/suspension system tower mount for a heavy-duty vehicle which mounts a force reacting suspension component attached to the vehicle frame members to the axle of the axle/suspension system. The tower mount includes an axle wrap system which attaches the tower mount to the axle of the axle/suspension system at a location inboard of the axle/suspension system suspension assemblies. The axle/suspension system tower mount provides mounting support for components of an air brake system, including cam shaft assemblies, brake air chambers, and mounting brackets thereof.

A method of on-demand energy delivery to an active suspension system is disclosed. The suspension system includes an actuator body, a hydraulic pump, an electric motor, a plurality of sensors, an energy storage facility, and a controller. The method includes disposing an active suspension system in a vehicle between a wheel mount and a vehicle body, detecting a wheel event requiring control of the active suspension; and sourcing energy from the energy storage facility and delivering it to the electric motor in response to the wheel event.

A leaning vehicle has a frame; a shock tower pivotally connected to the frame; front left and right ground engaging members; front left and right suspension assemblies; portions of the front left suspension assembly, the front left ground engaging member and other components of the vehicle suspended by the front left suspension assembly have a first unsprung mass; portions of the front right suspension assembly, the front right ground engaging member and other components of the vehicle suspended by the front right suspension assembly have a second unsprung mass; a moment of inertia of the shock tower being at least twenty-five percent of a combined moment of inertia of the first and second unsprung masses; a steering assembly; a rear suspension assembly; at least one rear ground engaging; and a motor.

Aspects of the disclosure relate to a mechanical joint with five degrees of freedom. In certain embodiments, the mechanical joint includes first and second triangular linkages. The first triangular linkage includes a base end configured to hingedly couple to a first body to pivot relative to the first body and a vertex end that includes a first rotational member. The second triangular linkage includes a base end configured to hingedly couple to a second body to pivot relative to the second body and a vertex end that includes a second rotational member. The first rotational member and the second rotational member are rotationally coupled to form a all joint. With this joint, the second body is moveable in two translational degrees of freedom and restricted in one translational degree of freedom relative to the first body. Such a configuration allows vertical movement and/or reduces stress on the joint.

The invention relates to a vehicle seat or a vehicle cab with a suspension system comprising an upper closing part and a lower closing part which is deflectable in relation to the upper closing part, which closing parts are connected to each other in a resilient manner by means of a suspension element, and with a damping system for damping vibrations acting on at least one of the two closing parts, wherein the damping system and a distance levelling system for adjusting a distance between the upper closing part and the lower closing part have a common fluid actuator element controlled by compression and tension stages.

A pneumatic suspension system for a vehicle is provided comprising a mounting arrangement for mounting a portion of the vehicle on a chassis; the mounting arrangement including at least one pneumatic spring to be arranged and coupled between the portion of the vehicle and the vehicle chassis. A vehicle state control system is provided that provides a pressure set value in the pneumatic spring and a pressure controller is arranged to a valve device alternatively for pressurizing or depressurizing the each pneumatic spring. The valve device comprises at least a first valve having a valve outlet coupled to the spring terminal and a valve inlet communicatively coupled to the pressure terminal. A support structure (102) distinct from the sealing edge (104) is provided arranged to providing supporting contact to the sealing face to counteract deformations of the sealing face.

A torsion device comprising: a first part comprising a first resilient torsion member including: a first support end; a first free end spaced from the first support end; and a first engagement region; a second part comprising a second resilient torsion member including: a second support end; a second free end spaced from the second support end; and a second engagement region; wherein the second part is rotatable relative to the first part about an axis of rotation (A) between a first angular position and a second angular position, and the first and second torsion members are configured to urge the first and second engagement regions together to cause flexure of at least one of the first and second resilient torsion members as the second part rotates relative to the first part from the first angular position to the second angular position.

The vehicle includes: a chassis which includes a front cross-member and a rear cross-member; a nacelle receiving a person or a load, pivotally mounted relative to the central part of the cross-members about a substantially longitudinal hinge axis, the center of gravity of the nacelle being situated below said hinge axis; a front train and a rear train, each including two movement supports on the ground, each movement support being connected to the end part of the corresponding cross-member by a connecting system; the cross-members, situated in the upper part of the nacelle, being separate pieces linked together only by the nacelle, via the hinge axis, so as to be able to pivot about the hinge axis independently of one another.