A shock absorber having a plurality of pistons in a telescopic or nested configuration. The shock absorber has a first shaft with a first piston disposed within a cylinder filled with a hydraulic fluid. A second shaft is in turn disposed within the first shaft, the second shaft having a second piston extending beyond the position of the first piston. The second shaft is further coupled to a vehicle's suspension system. When undergoing a displacement, the second piston moves through the cylinder and compresses an external spring. After the second shaft has been fully extended, the first piston is then actuated, thereby also moving through the hydraulic fluid. As the pistons traverse through the cylinder, a volume of the fluid is pushed into a reservoir communicated to the cylinder. Both the first and second shafts are configured to move independently with respect to each other and to the cylinder.

A vehicle suspension damper including: a cylinder; a piston assembly; and an adjuster, wherein the piston assembly compresses fluid as it moves within the cylinder and the adjuster obstructs fluid flow from a first side of a damping piston of the piston assembly to a second side of the damping piston.

An apparatus and system are disclosed that provide position sensitive suspension damping. A damping unit includes a piston mounted in a fluid-filled cylinder. A vented path in the piston may be fluidly coupled to a bore formed in one end of the piston rod, creating a flow path for fluid to flow from a first side of the piston to a second side of the piston during a compression stroke. The flow path may be blocked by a needle configured to engage the bore as the damping unit is substantially fully compressed, thereby causing the damping rate of the damping unit to increase. In one embodiment, the piston includes multiple bypass flow paths operable during the compression stroke or the rebound stroke of the damping unit. One or more of the bypass flow paths may be restricted by one or more shims mounted on the piston.

A method and apparatus for a shock absorber for a vehicle having a gas spring with first and second gas chambers, wherein the first chamber is utilized during a first travel portion of the shock absorber and the first and second chambers are both utilized during a second portion of travel. In one embodiment, a travel adjustment assembly is configured to selectively communicate a first gas chamber with a negative gas chamber.

A position-relative damper assist system (1) for use with a vehicle, the position-relative damper assist system (1) comprising top and bottom mounting components (5,3), a piston assembly (9), an adjustment assembly (19), and a biasing assembly (21). The piston assembly (9) is operatively disposed between the top and bottom mounting components (5,3), and has a piston head (11) being displaceable within a chamber (13), and being provided with at least one fluid passage (15) for allowing fluid (17) of the chamber (13) to travel therethrough, in order to provide a corresponding damping effect. The adjustment assembly (19) cooperates with the piston head (11) of the piston assembly (9) for adjustably varying an effective cross-sectional profile of the at least one fluid passage (15) in order to in turn vary a corresponding flow rate of fluid (17) passing through said at least one fluid passage (15), and in turn vary the resulting damping effect. The biasing assembly (21) cooperates with the adjustment assembly (19) for selectively varying a configuration of the adjustment assembly (19) in response to a given input indicative of the positioning of the piston assembly (9) within a stroke distance (7), in order in vary the resulting damping effect in response to a corresponding displacement-profile (23) provided by the biasing assembly (21).

A method for servicing a dual-stage, mixed gas/fluid shock strut may comprise measuring a servicing temperature, charging a secondary gas chamber with compressed gas, wherein a secondary chamber pressure corresponds to the servicing temperature, pumping oil into a primary chamber of the shock strut, and charging the primary chamber with compressed gas.

A position-relative damper assist system (1) for use with a vehicle, the position-relative damper assist system (1) comprising top and bottom mounting components (5, 3), a piston assembly (9), an adjustment assembly (19), and a biasing assembly (21). The piston assembly (9) is operatively disposed between the top and bottom mounting components (5, 3), and has a piston head (11) being displaceable within a chamber (13), and being provided with at least one fluid passage (15) for allowing fluid (17) of the chamber (13) to travel therethrough, in order to provide a corresponding damping effect. The adjustment assembly (19) cooperates with the piston head (11) of the piston assembly (9) for adjustably varying an effective cross-sectional profile of the at least one fluid passage (15) in order to in turn vary a corresponding flow rate of fluid (17) passing through said at least one fluid passage (15), and in turn vary the resulting damping effect. The biasing assembly (21) cooperates with the adjustment assembly (19) for selectively varying a configuration of the adjustment assembly (19) in response to a given input indicative of the positioning of the piston assembly (9) within a stroke distance (7), in order in vary the resulting damping effect in response to a corresponding displacement-profiled (23) provided by the biasing assembly (21).

A vehicle suspension damper including: a cylinder; a piston assembly; and an adjuster, wherein the piston assembly compresses fluid as it moves within the cylinder and the adjuster obstructs fluid flow from a first side of a damping piston of the piston assembly to a second side of the damping piston.

Provided is a shock absorber that includes a middle chamber formed by a piston, a first damping-force generating device that is provided between an upper chamber and the middle chamber and generates a damping force, a second damping-force generating device that is provided between a lower chamber and the middle chamber and generates a damping force, and a position-based state changing device that changes a state of a passage to a state in which the upper chamber and the lower chamber communicate with each other, a state in which the upper chamber and the middle chamber communicate with each other, or a state in which the lower chamber and the middle chamber communicate with each other depending on a position of the piston.

A damping actor selector may be configured to transition a multi-actor damping system from a first damping actor configuration to a second damping actor configuration. The multi-actor damping system may be used in a shock strut assembly to alter a damping curve of the shuck strut assembly. The damping actor selector may be coupled to a metering pin of a shock strut assembly. The damping actor selector may be configured to rotate the metering pin to transition the multi-actor damping system from a first damping actor configuration to a second damping actor configuration. The first damping actor configuration may correspond to a first damping curve. The second damping actor configuration may correspond to a second damping curve. The first damping curve being different than the second damping curve.