Movers and shakers: Granular damping in microgravity

M. N. Bannerman; J. E. Kollmer; A. Sack; M. Heckel; P. Mueller; T. Poeschel

doi:10.1103/PhysRevE.84.011301

Movers and shakers: Granular damping in microgravity

M. N. Bannerman, J. E. Kollmer, A. Sack, M. Heckel, P. Mueller, T. Poeschel

Engineering

Inst Multiscale Simulat

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65 Citations (Scopus)

Abstract

The response of an oscillating granular damper to an initial perturbation is studied using experiments performed in microgravity and granular dynamics simulations. High-speed video and image processing techniques are used to extract experimental data. An inelastic hard sphere model is developed to perform simulations and the results are in excellent agreement with the experiments. In line with previous work, a linear decay of the amplitude is observed. Although this behavior is typical for a friction-damped oscillator, through simulation it is shown that this effect is still present even when friction forces are absent. A simple expression is developed which predicts the optimal damping conditions for a given amplitude and is independent of the oscillation frequency and particle inelasticities.

Original language	English
Article number	011301
Number of pages	9
Journal	Physical Review. E, Statistical, Nonlinear and Soft Matter Physics
Volume	84
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevE.84.011301
Publication status	Published - 6 Jul 2011

Keywords

impact dampers
dissipative properties
particle dampers
vibration
simulatiom
plates

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10.1103/PhysRevE.84.011301

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abstract = "The response of an oscillating granular damper to an initial perturbation is studied using experiments performed in microgravity and granular dynamics simulations. High-speed video and image processing techniques are used to extract experimental data. An inelastic hard sphere model is developed to perform simulations and the results are in excellent agreement with the experiments. In line with previous work, a linear decay of the amplitude is observed. Although this behavior is typical for a friction-damped oscillator, through simulation it is shown that this effect is still present even when friction forces are absent. A simple expression is developed which predicts the optimal damping conditions for a given amplitude and is independent of the oscillation frequency and particle inelasticities.",

keywords = "impact dampers, dissipative properties, particle dampers, vibration, simulatiom, plates",

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AU - Bannerman, M. N.

AU - Kollmer, J. E.

AU - Sack, A.

AU - Heckel, M.

AU - Mueller, P.

AU - Poeschel, T.

PY - 2011/7/6

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AB - The response of an oscillating granular damper to an initial perturbation is studied using experiments performed in microgravity and granular dynamics simulations. High-speed video and image processing techniques are used to extract experimental data. An inelastic hard sphere model is developed to perform simulations and the results are in excellent agreement with the experiments. In line with previous work, a linear decay of the amplitude is observed. Although this behavior is typical for a friction-damped oscillator, through simulation it is shown that this effect is still present even when friction forces are absent. A simple expression is developed which predicts the optimal damping conditions for a given amplitude and is independent of the oscillation frequency and particle inelasticities.

KW - impact dampers

KW - dissipative properties

KW - particle dampers

KW - vibration

KW - simulatiom

KW - plates

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JF - Physical Review. E, Statistical, Nonlinear and Soft Matter Physics

IS - 1

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Movers and shakers: Granular damping in microgravity

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Keywords

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