The vibration attenuation system includes a load bearing layer, a non-load bearing layer, and a rigid beam connector. The load bearing layer has a first density and a first stiffness. The non-load bearing layer has a second density and a second stiffness. The second density is lower than the first density. The rigid beam connector has a third density and a third stiffness. The rigid beam connector couples the load bearing layer to the non-load bearing layer. The coupling of the non-load bearing layer to the load bearing layer is enabled through the use of the rigid beam connector which provides a nonlocal connection to transfer energy from the load bearing layer to the non-load bearing layer.

The vibration attenuation system includes a load bearing layer, a non-load bearing layer, and a rigid beam connector. The load bearing layer has a first density and a first stiffness. The non-load bearing layer has a second density and a second stiffness. The second density is lower than the first density. The rigid beam connector has a third density and a third stiffness. The rigid beam connector couples the load bearing layer to the non-load bearing layer. The coupling of the non-load bearing layer to the load bearing layer is enabled through the use of the rigid beam connector which provides a nonlocal connection to transfer energy from the load bearing layer to the non-load bearing layer.

The present invention relates to a tower damper adapted to be mounted in a wind turbine tower, the tower damper comprising a pendulum structure adapted to be suspended in the wind turbine tower, said pendulum structure comprising a pendulum body, a chamber holding a damping liquid into which damping liquid the pendulum structure is at least partly immersed, a plurality of damping elements arranged to dampen movements of the pendulum structure when suspended in the wind turbine tower, the plurality of damping elements comprising a foam portion composed of a resilient and porous foam material, and a suspension arrangement for suspending the pendulum structure in the wind turbine tower such that the pendulum structure is allowed to displace from a neutral position for the pendulum structure.

The present invention relates to a tower damper adapted to be mounted in a wind turbine tower, the tower damper comprising a pendulum structure adapted to be suspended in the wind turbine tower, said pendulum structure comprising a pendulum body, a chamber holding a damping liquid into which damping liquid the pendulum structure is at least partly immersed, a plurality of damping elements arranged to dampen movements of the pendulum structure when suspended in the wind turbine tower, the plurality of damping elements comprising a foam portion composed of a resilient and porous foam material, and a suspension arrangement for suspending the pendulum structure in the wind turbine tower such that the pendulum structure is allowed to displace from a neutral position for the pendulum structure.

The present invention relates to a wind turbine tower comprising a tower vibration damper (100) with a tuned mass damper and one or more impact damping units (113, 114, 115, 200, 300, 400). The tuned mass damper comprises a pendulum structure (101, 208), a chamber connecting a friction media (112) to the pendulum structure (101, 208) is at least partly immersed, and a suspension arrangement (103-111) suspending the pendulum structure (101, 208) inside the wind turbine tower such that the pendulum structure (101) is allowed to displace from a neutral position towards the outer boundary (102) of the chamber. The impact damping units (113, 114, 115, 200, 300, 400) are positioned between the pendulum structure (101, 208) and the outer boundary (102), such that the outer boundary (102) of the chamber and the pendulum structure (101, 208) may collide via the impact damping units (113, 114, 115, 200, 300, 400).

The present invention relates to a wind turbine tower comprising a tower vibration damper (100) with a tuned mass damper and one or more impact damping units (113, 114, 115, 200, 300, 400). The tuned mass damper comprises a pendulum structure (101, 208), a chamber connecting a friction media (112) to the pendulum structure (101, 208) is at least partly immersed, and a suspension arrangement (103-111) suspending the pendulum structure (101, 208) inside the wind turbine tower such that the pendulum structure (101) is allowed to displace from a neutral position towards the outer boundary (102) of the chamber. The impact damping units (113, 114, 115, 200, 300, 400) are positioned between the pendulum structure (101, 208) and the outer boundary (102), such that the outer boundary (102) of the chamber and the pendulum structure (101, 208) may collide via the impact damping units (113, 114, 115, 200, 300, 400).

A pressure buffer stop for a vibration damper that comprises for being at least partially received in a dome bearing housing an outer contour and for coaxial arrangement on a piston rod of the vibration damper a hollow-cylindrical basic structure with an inner contour, wherein the outer contour of the pressure buffer stop comprises in at least one region for being at least partially received in the dome bearing housing a three-dimensionally structured surface.

A pressure buffer stop for a vibration damper that comprises for being at least partially received in a dome bearing housing an outer contour and for coaxial arrangement on a piston rod of the vibration damper a hollow-cylindrical basic structure with an inner contour, wherein the outer contour of the pressure buffer stop comprises in at least one region for being at least partially received in the dome bearing housing a three-dimensionally structured surface.

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).