Pourtavakoli H, Ribeiro Parteli EJ, Pöschel T (2016)
Publication Language: English
Publication Type: Journal article, Original article
Publication year: 2016
Book Volume: 18
Article Number: 073049
DOI: 10.1088/1367-2630/18/7/073049
By means of particle-based numerical simulations using the discrete element method, we address the question of how the performance of granular dampers is affected by the shape of the granular particles. In consistence with previous experiments performed with nearly spherical particles we find that independently of the particles‘ shape, the granular system is characterized by a gas-like regime for small amplitudes of the container’s oscillation and by a collect-and-collide regime for large amplitude forcing. Both regimes are separated by an optimal operation mode—the critical amplitude of the damping oscillation for which the energy dissipation is maximal—which is independent of the particle shape for given conditions of particle mass, material properties and number of particles. However, in the gas-like regime, we find that spherical particles lead to more efficient energy dissipation compared to complex shaped particles of the same mass. In this regime, a dependence on the damper’s efficiency on the particle shape is found.
APA:
Pourtavakoli, H., Ribeiro Parteli, E.J., & Pöschel, T. (2016). Effect of particle shape on the efficiency of granular dampers. New Journal of Physics, 18. https://doi.org/10.1088/1367-2630/18/7/073049
MLA:
Pourtavakoli, Hamzeh, Eric Josef Ribeiro Parteli, and Thorsten Pöschel. "Effect of particle shape on the efficiency of granular dampers." New Journal of Physics 18 (2016).
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