A linear actuator comprising a housing with a proximal end and a distal end, the housing defining a central cavity extending axially through the housing; a piston tube, where a first portion of the piston tube is slidably positioned axially in the housing, and a second portion of the piston tube extends outwardly from the distal end of the housing; an elongated rotatable screw positioned axially within the central cavity of the housing; a nut positioned within the housing and mounted about the screw, the nut configured to move axially within the housing as the screw rotates; and a spring positioned around the screw, the spring positioned within the housing between the nut and the piston tube; wherein the spring is configured to bias the piston tube away from the nut.

A bearing spring/damper system of a vehicle wheel has a hydraulic vibration damper consisting of a damper cylinder and a damper piston guided therein, the piston rod of which hydraulic vibration damper is fastened to the vehicle body, whilst the damper cylinder is supported to a wheel guiding element. A pretension spring is clamped functionally between the damper piston and a pretension piston which can be displaced hydraulically in the longitudinal direction of the piston rod. The pretension piston is supported hydraulically with respect to the damper cylinder by a support chamber filled with the hydraulic medium of the vibration damper, and can be displaced by a conveying device, which conveys hydraulic medium into or out of the support chamber. The pretension spring is parallel-connected in every possible position of the pretension piston of a bearing spring ultimately clamped between the vehicle body and the wheel for force transmission.

A system/assembly for a suspension fork for a bicycle is disclosed. The fork may comprise a compression system and an adjustment mechanism configured for adjustment of compression damping and adjustment of travel. Adjustment of travel reduces compression stroke distance within the full length of travel. The adjustment mechanism may be configured for at least two settings for compression damping and at least two settings for adjustment of travel. Settings for compression damping may comprise a setting with adjustment of compression damping but no adjustment of travel and a setting with adjustment of compression damping and adjustment of travel. Settings for adjustment of travel may comprise a travel-adjust setting where the stroke distance is reduced and a setting where the stroke distance may be the full length of travel. The adjustment mechanism may provide for performance adjustment at an adjuster. The fork may comprise a rebound system with an adjuster.

Provided herein is a bump stop including a cylindrical body, a cylindrical shaft positioned within the cylindrical body and axially aligned with the cylindrical body, a top retainer and a bottom retainer each connected to an end of the cylindrical body. The cylindrical shaft protrudes through the bottom retainer. A spring is connected to one end of the cylindrical shaft and is connected to the top retainer. A shear thickening fluid disposed in the cylindrical body, between the cylindrical body and the cylindrical shaft. The cylindrical shaft includes an obstruction perpendicular to an axis of the cylindrical shaft, and the obstruction and the shear thickening fluid affect control of movement of the cylindrical shaft under impact.

A height adjustable top mount for adjusting a ride height of a vehicle comprising includes a top plate, a worm wheel, a core, and worm gear. The top plate is configured to mount to a body of the vehicle and movable between a first position and a second position. The worm wheel is received in the top plate and includes an inner wheel surface and an outer wheel surface. The core is received within the worm wheel and helically meshed to the inner wheel surface of the worm wheel. The worm gear is meshed to the outer wheel surface of the worm wheel. Rotation of the worm gear drives rotation of the worm wheel, rotation of the worm wheel simultaneously moves the top plate vertically relative to the core, and movement of the top plate adjusts the ride height of the vehicle in a corresponding direction.

A vibration damper includes an end-stop control valve that progressively adds end-of-stroke damping force to complement the damping force provided by a main piston. The end-stop control valve may include a valve piston assembly that has a valve piston insert, a piston that is disposed radially outside the valve piston insert, and a valve disc stack-up that is supported on a hub of the valve piston insert and a valve seat of the piston. The valve piston insert and the piston may be arranged so as to be longitudinally movable relative to one another. Consequently, the preload of the valve disc stack-up increases as the valve piston assembly contacts a catch piston and begins end-of-stroke damping. Transitioning from an initial preload to a maximum preload during the end-of-stroke damping event progressively increases damping resistance and thereby improves NVH characteristics.

An end-stop control valve can progressively add end-of-stroke damping resistance to complement the damping force provided by a main piston in a damper tube. The end-stop control valve may include a piston that selectively engages with a catch piston, both of which are longitudinally movable within the damper tube. To reduce bypass around the piston, a piston band wrapped at least partially around the piston may engage with a sidewall of the catch piston just prior to engagement of the catch piston and the piston, although at least some hydraulic fluid can flow through a pathway of the piston band. A spring disc that moves with the piston may also engage with the catch piston just prior to engagement between the catch piston and the piston. The spring disc may elastically deform to contribute end-of-stroke resistance leading up to engagement of the piston and the catch piston.

A cylinder apparatus is provided with a stopper mechanism that operates when a piston rod extends and moves toward an upper end portion in an inner cylinder. This stopper mechanism includes a second cylinder provided movably relative to the piston rod and including a bottom portion on an upper end side in the inner cylinder and a cylinder portion extending from the bottom portion toward a lower end side, and a second piston provided so as to be able to move along with a movement of the piston rod to be fitted to the second cylinder. While being configured in this manner, the cylinder apparatus is configured in such a manner that a spring member 21 is provided between the second cylinder and a rod guide.

A damper assembly includes a main tube disposed on a center axis and extending between a first and a second end defining a fluid chamber for containing a working fluid. A main piston is slidably disposed in the fluid chamber dividing the fluid chamber into a rebound chamber and a compression chamber. A piston rod is attached to the main piston for moving the main piston between a compression and a rebound stroke. The piston rod includes a rod extender attached to the main piston defining a compartment. A compression stop including an additional piston is slidably disposed in the compartment and movable between a first position in response to the compression stroke and a second position in response to the rebound stroke. The first position is the additional piston being disposed adjacent the main piston. The second position is the additional piston being axially spaced from the main piston.

A height adjustable top mount for adjusting a ride height of a vehicle comprising includes a top plate, a worm wheel, a core, and worm gear. The top plate is configured to mount to a body of the vehicle and movable between a first position and a second position. The worm wheel is received in the top plate and includes an inner wheel surface and an outer wheel surface. The core is received within the worm wheel and helically meshed to the inner wheel surface of the worm wheel. The worm gear is meshed to the outer wheel surface of the worm wheel. Rotation of the worm gear drives rotation of the worm wheel, rotation of the worm wheel simultaneously moves the top plate vertically relative to the core, and movement of the top plate adjusts the ride height of the vehicle in a corresponding direction.