Andere Kunden interessierten sich auch für
![Sprays Diesel par le système common rail]( "Sprays Diesel par le système common rail")
Sprays Diesel par le système common rail51,99 €![Active Vibration Control of Structures for Earthquakes]( "Active Vibration Control of Structures for Earthquakes")
Active Vibration Control of Structures for Earthquakes51,99 €![Design optimization and vibration control of adaptive structures]( "Design optimization and vibration control of adaptive structures")
Design optimization and vibration control of adaptive structures44,99 €![Guidance and Control of Ships]( "Guidance and Control of Ships")
Guidance and Control of Ships44,99 €![Semi-active Intelligent Suspension System]( "Semi-active Intelligent Suspension System")
Semi-active Intelligent Suspension System44,99 €![Numerical simulation of two phase flows]( "Numerical simulation of two phase flows")
Numerical simulation of two phase flows51,99 €![Multidimensional Viscous FLows with Heat Transfer]( "Multidimensional Viscous FLows with Heat Transfer")
Multidimensional Viscous FLows with Heat Transfer44,99 €
In this work, an advanced active vibration control system acting on a railway vehicle multibody dynamic model is applied to show the possible reduction of rail car body vibration amplitudes to improve ride comfort. The control concept uses Piezo stack actuators directly acting on the rail car body structure. Several promising actuator positioning cases are evaluated in various excitation scenarios by co-simulation of the multibody system dynamics in the SimPACK® simulation environment and the online vibration control algorithm in MatLab/SIMULINK®. This way, a meaningful analysis of the system in its full complexity is carried out, showing the achievable improvement in ride comfort. Besides the simulation setup and results, this work contains a step by step instruction of the controller design procedure. There, critical decisions in the control design process are pointed out. A detailed modeling of the piezoelectric actuators is performed to address non-linearities and to show compensation measures. The concluding result interpretation and outlook discuss the capabilities of the approach and provides guidelines for the choice and placement of actuators for real railway vehicles.