Provided is a shock absorber capable of suppressing a great change in a damping force even upon a stroke change. The shock absorber with a pilot chamber includes: a housing that constitutes the pilot chamber and includes a pilot hole and an inflow passage; a disk valve body that allows a fluid inside the pilot chamber to be discharged outside via the pilot hole; and a check valve body that allows the fluid to flow into the pilot chamber through the inflow passage.

An air spring for damping and controlling a level position of a drivers cab or of a motor vehicle includes a lid, a rolling piston and at least one air spring bellows. At least one damping device is integrated into the air spring. A level control system is integrated into the air spring and is configured to at least one of supply and discharge compressed air, gas or a compressible medium so as to control the level position of the driver's cab or of the motor vehicle.

An air spring for damping and controlling a level position of a drivers cab or of a motor vehicle includes a lid, a rolling piston and at least one air spring bellows. At least one damping device is integrated into the air spring. A level control system is integrated into the air spring and is configured to at least one of supply and discharge compressed air, gas or a compressible medium so as to control the level position of the driver's cab or of the motor vehicle.

A damper valve with an adjustable effective stiffness of a shim. The damper valve includes a piston. The piston has a fluid path formed therethrough. A shim is disposed proximate the fluid path formed through the piston. A stiffness adjustment feature is coupled to the shim, and the shim is disposed between the piston and the stiffness adjustment feature. The stiffness adjustment feature is configured to adjust the effective stiffness of the shim without affecting a preload applied to the shim.

A damper valve with an adjustable effective stiffness of a shim. The damper valve includes a piston. The piston has a fluid path formed therethrough. A shim is disposed proximate the fluid path formed through the piston. A stiffness adjustment feature is coupled to the shim, and the shim is disposed between the piston and the stiffness adjustment feature. The stiffness adjustment feature is configured to adjust the effective stiffness of the shim without affecting a preload applied to the shim.

A control arrangement for a frequency-dependent damping valve of a vibration damper having a control pot with a cylindrical pot wall and a pot base adjoining the pot wall, a control piston arranged axially displaceable in the control pot between first and second end positions. The pot base has a deformation portion produced by plastic deformation that defines the first end position. The control piston is slidingly guided at a guide bush. The deformation portion defines a trough in which the guide bush is received by a first axial end and a spring unit supported at the control piston acts on the control piston with a spring force. The guide bush has a cutout at the first axial end arranged in the trough and in which a base material of the control base is displaced by plastic deformation to form a positive engagement connection.

A control arrangement for a frequency-dependent damping valve of a vibration damper having a control pot with a cylindrical pot wall and a pot base adjoining the pot wall, a control piston arranged axially displaceable in the control pot between first and second end positions. The pot base has a deformation portion produced by plastic deformation that defines the first end position. The control piston is slidingly guided at a guide bush. The deformation portion defines a trough in which the guide bush is received by a first axial end and a spring unit supported at the control piston acts on the control piston with a spring force. The guide bush has a cutout at the first axial end arranged in the trough and in which a base material of the control base is displaced by plastic deformation to form a positive engagement connection.

A vehicle damper is described. The vehicle damper includes: a cylinder; a piston within the cylinder; a working fluid within the cylinder; a reservoir in fluid communication with the cylinder via the working fluid, the reservoir operable to receive the working fluid from the cylinder in a compression stroke; a valve in a flow path between the cylinder and the reservoir; and a remotely-operable valve having a position allowing the working fluid to significantly by-pass the valve.

A cylinder device includes a recess provided on either one of the piston and the cylinder, the recess facing the other one of the piston and the cylinder; an extension-side discharge passage configured to permit only a flow of liquid from the extension-side chamber toward the recess; a compression-side discharge passage configured to permit only a flow of liquid from the compression-side chamber toward the recess; a tank-side discharge passage configured to allow the extension-side discharge passage and the compression-side discharge passage to communicate with the tank through the recess; an extension-side damping force generation passage configured to apply a resistance to a flow of liquid passing therethrough so as to exert a damping force during extension; and a compression-side damping force generation passage configured to apply a resistance to a flow of liquid passing therethrough so as to exert a damping force during contraction.

A cylinder device includes a recess provided on either one of the piston and the cylinder, the recess facing the other one of the piston and the cylinder; an extension-side discharge passage configured to permit only a flow of liquid from the extension-side chamber toward the recess; a compression-side discharge passage configured to permit only a flow of liquid from the compression-side chamber toward the recess; a tank-side discharge passage configured to allow the extension-side discharge passage and the compression-side discharge passage to communicate with the tank through the recess; an extension-side damping force generation passage configured to apply a resistance to a flow of liquid passing therethrough so as to exert a damping force during extension; and a compression-side damping force generation passage configured to apply a resistance to a flow of liquid passing therethrough so as to exert a damping force during contraction.