Particle dampers are simply designed passive damping elements. Granular particles are embedded in a container attached to a vibrating structure or within holes embedded in the vibrating structure. Due to the structural vibrations momentum is transferred to the granular material and energy is dissipated due to inter-particle impacts and frictional effects. In the last decades there has been an increased interest in particle dampers. Particle damping is easy to apply even in already existing hardware and it has been shown that it can be at least as effective as other damping techniques. This effectiveness in dissipating energy is not restricted to a single frequency but exists over a broader frequency range which is not usual in conventional damping solutions. Moreover, particle dampers are highly adaptive with various forms and sizes and a variety of particle types and materials.Despite the efficiency of particle dampers which was demonstrated experimentally, so far they have been used only in few different engineering applications, mostly designed for a very specific system. This might be due to the fact, that the processes in the particle dampers are very complex and not fully understood yet. Also the design process is currently mostly based on experimental trial-and-error strategies.The research objective is the development of a new simulation-based design methodology for passive vibration damping of lightweight structures and machines using distributed particle dampers. By such a new simulation-based design methodology, which is in parts independent of the specific application, it will be possible to extend particle dampers to a variety of very different applications. This is especially of interest for lightweight systems where currently often efficient passive vibration damping methods are lacking. Firstly, independent of the application, it is aimed to develop small particle damper units with predefined characteristics. These individual particle dampers should form an assembly set, which is ultimately used in the overall damping concept for specific applications. Thereby, several of these particle dampers, possibly with different characteristics, should be distributed optimally over a flexible body in order to achieve a maximal damping efficiency over a wide range of frequencies and amplitudes. For numerical studies Discrete-Element-Method models and macro-models, which can be more easily integrated in flexible multibody systems, are developed. These models are the basis for the damper development. The numerical work is closely accompanied by experimental investigations. As motivation example the application of the developed methods on an active flexible multibody system is chosen.

DFG Programme Research Grants