A hydraulic flow adjuster includes a first hydraulic tank, a second hydraulic tank, and a piston actuator. A first piston operates within the first hydraulic tank and a second piston operates within the second hydraulic tank. The piston actuator adjusts a relative position of the first piston in the first hydraulic tank and a relative position of the second piston position in the second hydraulic tank, such that the relative position of the first piston in the first hydraulic tank is the same as the relative position of the second piston in the second hydraulic tank.

A shock absorber includes a cylinder, a spring, a receiving member, a sensor, and a coupling member. The sensor includes a coil portion, and a core portion. The coupling member is formed integrally with the core portion. A recessed portion is formed in one of the receiving member and the coupling member, a protruding portion facing the recessed portion is formed in the other one of the receiving member and the coupling member, and the receiving member and the coupling member are coupled to each other via the recessed portion and the protruding portion.

A shock absorber includes a cylinder, a spring, a receiving member, a sensor, and a coupling member. The sensor includes a coil portion, and a core portion. The coupling member is formed integrally with the core portion. A recessed portion is formed in one of the receiving member and the coupling member, a protruding portion facing the recessed portion is formed in the other one of the receiving member and the coupling member, and the receiving member and the coupling member are coupled to each other via the recessed portion and the protruding portion.

A suspension assembly for a bicycle is disclosed. The suspension assembly may be configured to use a volume of fluid in a fluid circuit for damping and may comprise a damping mechanism; the suspension assembly may comprise a lockout mechanism independent of the damping mechanism configured to prevent damping by the damping mechanism and an actuator for the lockout mechanism. The lockout setting may be independent of the damping setting. A suspension system may comprise a fluid circuit for a fluid configured to provide damping for a bicycle; the suspension system may comprise a damping mechanism configured to provide a damping setting for damping and a lockout mechanism configured to provide a lockout setting and comprising (a) a flow control element (such as an adjuster shaft) configured in the lockout setting to prevent flow of the fluid through the damping mechanism and (b) a flow control element (such as a blow-off valve) configured to allow flow to a reservoir chamber of the fluid circuit if the pressure of the fluid is greater than a threshold value; an actuator for the lockout mechanism configured to actuate the flow control element configured to prevent flow through the damping mechanism; the lockout mechanism may configured to provide the lockout setting when on and to permit damping at the damping setting by the damping mechanism when off.

A suspension assembly for a bicycle is disclosed. The suspension assembly may be configured to use a volume of fluid in a fluid circuit for damping and may comprise a damping mechanism; the suspension assembly may comprise a lockout mechanism independent of the damping mechanism configured to prevent damping by the damping mechanism and an actuator for the lockout mechanism. The lockout setting may be independent of the damping setting. A suspension system may comprise a fluid circuit for a fluid configured to provide damping for a bicycle; the suspension system may comprise a damping mechanism configured to provide a damping setting for damping and a lockout mechanism configured to provide a lockout setting and comprising (a) a flow control element (such as an adjuster shaft) configured in the lockout setting to prevent flow of the fluid through the damping mechanism and (b) a flow control element (such as a blow-off valve) configured to allow flow to a reservoir chamber of the fluid circuit if the pressure of the fluid is greater than a threshold value; an actuator for the lockout mechanism configured to actuate the flow control element configured to prevent flow through the damping mechanism; the lockout mechanism may configured to provide the lockout setting when on and to permit damping at the damping setting by the damping mechanism when off.

A non-drive dynamic stabilizer includes a damper and an actuator. The dynamic stabilizer provides multiple states of support to a solar tracker structure. These states may include 1) flexible movement and/or damping during normal operation (i.e. tracking) and/or 2) rigid or locked, whereby the dynamic stabilizer acts as a restraint. The dynamic stabilizer is actuated by a control system according to the real-time demands on the structure. Sensors to provide input to the control system may include wind speed sensors, wind direction sensors, snow sensors, vibration sensors and/or displacement sensors.

A non-drive dynamic stabilizer includes a damper and an actuator. The dynamic stabilizer provides multiple states of support to a solar tracker structure. These states may include 1) flexible movement and/or damping during normal operation (i.e. tracking) and/or 2) rigid or locked, whereby the dynamic stabilizer acts as a restraint. The dynamic stabilizer is actuated by a control system according to the real-time demands on the structure. Sensors to provide input to the control system may include wind speed sensors, wind direction sensors, snow sensors, vibration sensors and/or displacement sensors.

Gas spring and gas damper assemblies include a flexible spring member. First and second end members are secured to opposing ends of the flexible spring member to form a spring chamber. The second end member includes an end member wall that at least partially defines a damping chamber within the second end member. A damper piston assembly includes a damper piston and an elongated damper rod. The damper piston separates the piston chamber into first and second chamber portions. A pneumatically-actuated control device is disposed in fluid communication with one of the first and second chamber portions. The control device is selectively operable to alter the functionality of the gas spring and gas damper assembly between spring and damper functionality and actuator functionality. Suspension systems including one or more of such gas spring and gas damper assemblies as well as methods of operation are also included.

A hydraulic fluid supply system, in particular for a suspension system, having a pump for supplying a connection of the hydraulic fluid supply system for a connectable actuator. Starting from the pump, a minimum-pressure-maintaining valve having a control connection for the connectable actuator, is operatively provided upstream of the connection.

A hydraulic fluid supply system, in particular for a suspension system, having a pump for supplying a connection of the hydraulic fluid supply system for a connectable actuator. Starting from the pump, a minimum-pressure-maintaining valve having a control connection for the connectable actuator, is operatively provided upstream of the connection.