Abstract: A method for detecting a defective damper device of a vehicle, including the following steps: monitoring the specific damper travel values (DW) of at least two wheel carriers of the vehicle in a monitoring period (UZ), determining the specific damper speeds (DG) and the specific damper accelerations (DB) on the basis of the monitored specific damper travel values (DW) in the monitoring period (UZ), acquiring the specific damper work values (DA) on the basis of the determined specific damper speeds (DG) and on the basis of the determined specific damper accelerations (DB), generating a comparison result (VE) from a comparison of the acquired specific damper work values (DA) with one another, and generating at least one specific status signal (SS) on the basis of the comparison result (VE) for the at least two wheel carriers.

Abstract: A method for detecting a defective damper device of a vehicle, including the following steps: monitoring the specific damper travel values (DW) of at least two wheel carriers of the vehicle in a monitoring period (UZ), determining the specific damper speeds (DG) and the specific damper accelerations (DB) on the basis of the monitored specific damper travel values (DW) in the monitoring period (UZ), acquiring the specific damper work values (DA) on the basis of the determined specific damper speeds (DG) and on the basis of the determined specific damper accelerations (DB), generating a comparison result (VE) from a comparison of the acquired specific damper work values (DA) with one another, and generating at least, one specific status signal (SS) on the basis of the comparison result (VE) for the at least two wheel carriers.

Abstract: A test stand for dynamic testing of an individual running gear component or of a complete axle system of a motor vehicle includes a test stand frame having. The test stand frame has a mounting area configured for mounting the complete axle system in the mounting area in a first installation direction. A fastening device is configured for fixed mounting of the individual running gear component on the fastening device in a second installation direction, the second installation direction being different from the first installation direction. An actuator is configured for dynamic excitation of both of the complete axle system and the individual running gear component. The actuator is configured to connect to the individual running gear component or the complete axle system in a region of a point of intersection of the first installation direction and the second installation direction.

Abstract: A test stand for dynamic testing of an individual running gear component or of a complete axle system of a motor vehicle includes a test stand frame having. The test stand frame has a mounting area configured for mounting the complete axle system in the mounting area in a first installation direction. A fastening device is configured for fixed mounting of the individual running gear component on the fastening device in a second installation direction, the second installation direction being different from the first installation direction. An actuator is configured for dynamic excitation of both of the complete axle system and the individual running gear component. The actuator is configured to connect to the individual running gear component or the complete axle system in a region of a point of intersection of the first installation direction and the second installation direction.

Abstract: A vibration damper has a working cylinder and a working piston axially displaceable therein. A compensation cylinder has a compensation piston axially displaceable therein. The compensation cylinder is situated at the longitudinal end of the working cylinder and diagonally thereto.

Abstract: A vibration damper has a working cylinder and a working piston axially displaceable therein. A compensation cylinder has a compensation piston axially displaceable therein. The compensation cylinder is situated at the longitudinal end of the working cylinder and diagonally thereto.

Abstract: A hydraulic dashpot with a cylinder (1), a piston (4), and a bypass. The cylinder is charged with fluid. The piston partitions the cylinder into two compartments (7 & 8), travels back and forth therein on the end of a piston rod (2), and is provided with breaches and valves. The open cross-section of the bypass can be expanded and contracted and fixed in accordance with the direction the piston is traveling in, depending on whether the dashpot is in the compression or in the suction phase. The bypass is provided with an axially displaceable control component. One end of the control component comes to rest against a valve, its displacement being limited by stops. The bypass is accommodated in an axial bore through the piston rod. The bypass operates in conjunction with various outlets that open into the compartments. The control component is provided with at least one lateral flange and travels back and forth in at least one tube. The object is a smooth performance curve and low wear.

Abstract: A blow-off valve for a hydraulic dashpot comprising a fluid charged cylinder (1) and a piston (3) that travels back and forth therein on the end of a piston rod. The piston partitions the cylinder into two compartments (6 & 7) and is provided with breaches (4) and shock-absorbing valves. The piston rod (2) or an extension (8) thereof is hollow and accommodates operating components (13). The object is a valve that can be accommodated along with the hydraulic lines that serve it outside the piston rod or an extension thereof. The outer surface of the piston rod is accordingly provided with at least one axial inwardly undulating groove (14) at least as long as the piston, including its fastenings and operating components, is high. Alternatively, the bore that extends through the piston rod or its extension and its fastenings and operating components is provided with a similar radially outward groove that can be closed off at the compression end by a spring-loaded valve.

Abstract: A piston-rod assembly with a piston rod having at least one attachment at one end. The piston rod is fabricated of fiber reinforced composite. The piston rod has a body of fiber-reinforced ceramic with a basic matrix of carbon fibers or ceramic fibers or both wherein at least silicon carbide is embedded and with an open porosity, at least at the surface layer, of no more than 3% of the volume of that layer admitting lubricants into the pores. The at least one attachment (2, 18a, 19, or 22) includes at least one component of a non-ceramic material that fits into and/or interlocks with the piston rod.

Abstract: A resilient leg as part of an attachment for the wheel of a motor vehicle. The leg is provided with a piston rod (4) that has a piston (5) attached to it, that travels into and out of a housing (1), that is attached at its outer end to the vehicle's chassis, and that is maintained in radial alignment by two separated bearings. The piston divides the interior of the housing into two fluid-charged chambers (9 & 10). The object is to ensure satisfactory transmission of moments of force from the piston rod to the housing in a leg that is light in weight. The piston rod accordingly extends through, and is maintained in radial alignment at, both ends of the leg.