A hydraulic lift actuator for adjusting the height of a vehicle includes: a top mount plate configured for attachment to a chassis element; a hydraulic cylinder having a tubular wall and an end cap, together defining an interior chamber; a piston rod extending axially into the interior chamber; a piston assembly connected to the piston rod and disposed within the interior chamber, wherein the piston assembly divides the interior chamber into an upper chamber and a lower chamber, the lower chamber extending between the piston assembly and the end cap; and a spring seat rigidly connected to the hydraulic cylinder and configured to engage an upper end of a coil spring, wherein the spring seat and the hydraulic cylinder are linearly translatable relative to the piston rod between a retracted position adjacent to the top mount plate and an extended position spaced apart from the top mount plate.

An apparatus for dampening at least one optical instrument on a military platform. The apparatus includes a plate adapted to hold at least one optical instrument. The apparatus also includes at least one dampening assembly having a first end operably engaged with the plate and an opposing second end operably engaged with a platform. The at least one dampening assembly is also adapted to reduce the movement of the plate and optical device from a ballistic event created by a ballistic device on the platform.

A suspension (1) for a bicycle (101) comprising an elastic element (2) and a blocking/releasing device (3) of the elastic element (2). The blocking/releasing device (3) comprises:a closed hydraulic circuit (4) containing a working fluid (5);a cylinder-piston assembly (60) comprising a cylinder (10) and a piston (6) slidable inside said cylinder, said cylinder-piston assembly (60) being inserted in the hydraulic circuit (4) and being operatively disposed in parallel with said elastic element;a valve (8) commanded by an actuator (9) inserted in the hydraulic circuit (4) and configurable according to an open configuration, so that the working fluid (5) freely flows in the hydraulic circuit for enabling movements of the piston (6) inside the cylinder (10), and a closed configuration, so that the working fluid (5) is prevented from flowing in the hydraulic circuit (4) and the piston (6) is kept blocked by the working fluid (5);a main housing (11) receiving inside the cylinder-piston assembly (60); wherein the hydraulic circuit (4) is made in a space formed between the walls of the main housing (11) and the walls of the cylinder (10).

A suspension (1) for a bicycle (101) comprising an elastic element (2) and a blocking/releasing device (3) of the elastic element (2). The blocking/releasing device (3) comprises:a closed hydraulic circuit (4) containing a working fluid (5);a cylinder-piston assembly (60) comprising a cylinder (10) and a piston (6) slidable inside said cylinder, said cylinder-piston assembly (60) being inserted in the hydraulic circuit (4) and being operatively disposed in parallel with said elastic element;a valve (8) commanded by an actuator (9) inserted in the hydraulic circuit (4) and configurable according to an open configuration, so that the working fluid (5) freely flows in the hydraulic circuit for enabling movements of the piston (6) inside the cylinder (10), and a closed configuration, so that the working fluid (5) is prevented from flowing in the hydraulic circuit (4) and the piston (6) is kept blocked by the working fluid (5);a main housing (11) receiving inside the cylinder-piston assembly (60); wherein the hydraulic circuit (4) is made in a space formed between the walls of the main housing (11) and the walls of the cylinder (10).

An electromechanical chassis actuator includes a single electric motor and two screw drives. The two screw drives use a common threaded spindle. A spindle nut of the first screw drive is rotationally fixed to the electric motor's rotor and engages the threaded spindle in a back-driveable manner. A spindle nut of the second screw drive is selectively coupled to the electric motor's rotor by a coupler and engages the threaded spindle in a self-locking (not back-driveable) manner. When the coupler is in an engaged position, the actuator operates in a level-adjustment mode. When the coupler is in a released position, the actuator operates in a damping mode.

An electromechanical chassis actuator includes a single electric motor and two screw drives. The two screw drives use a common threaded spindle. A spindle nut of the first screw drive is rotationally fixed to the electric motor's rotor and engages the threaded spindle in a back-driveable manner. A spindle nut of the second screw drive is selectively coupled to the electric motor's rotor by a coupler and engages the threaded spindle in a self-locking (not back-driveable) manner. When the coupler is in an engaged position, the actuator operates in a level-adjustment mode. When the coupler is in a released position, the actuator operates in a damping mode.

A compression damper of a shock absorber includes: a single adjustable fluid circuit configured for controlling a damping rate associated with multiple compression speeds of the shock absorber, wherein the single adjustable fluid circuit includes a fluid passageway through a base valve; and a positionally adjustable floating shim stack positioned at one end of the fluid passageway, the positionally adjustable floating shim stack configured for selectively blocking a flow of fluid through the fluid passageway.

A compression damper of a shock absorber includes: a single adjustable fluid circuit configured for controlling a damping rate associated with multiple compression speeds of the shock absorber, wherein the single adjustable fluid circuit includes a fluid passageway through a base valve; and a positionally adjustable floating shim stack positioned at one end of the fluid passageway, the positionally adjustable floating shim stack configured for selectively blocking a flow of fluid through the fluid passageway.

A shock absorber includes a spring bearing that supports one end of the suspension spring which biases the shock absorber main body in an extension direction; a jack configured to change an axial position of the spring bearing; a ring-shaped adapter freely fitted to an outer periphery of the spring bearing; a restricting portion disposed between the spring bearing and the adapter, the restricting portion restricting a movement of the adapter in an axial direction with respect to the spring bearing; a rotation stop member mounted on the shock absorber main body to stop a rotation of the adapter; and a stroke sensor disposed between the adapter and the rotation stop member.

A bicycle fork includes a pair of fork leg assemblies, each of the leg assemblies having an upper leg telescopingly engaged with a lower leg. A damping assembly is provided in at least one of the legs. The damping assembly includes lock-out and blow-off compression circuits. These compression circuits are externally adjustable without tools. Furthermore, these two compression circuits may be adjusted independently of each other.