Three-dimensional simulations of a vertically vibrated granular bed including interstitial air

V. Idler; I. Sánchez; R. Paredes; G. Gutiérrez; L. I. Reyes; R. Botet

doi:10.1103/PhysRevE.79.051301

Three-dimensional simulations of a vertically vibrated granular bed including interstitial air

V. Idler
, I. Sánchez
, R. Paredes
, G. Gutiérrez
, L. I. Reyes
, R. Botet

Research output: Contribution to journal › Article › peer-review

Abstract

We present a numerical study of the effect of interstitial air on a vertically vibrated granular bed within one period of oscillation. We use a three-dimensional molecular-dynamics simulation including air phenomenologically. The simulations are validated with experiments made with spherical glass beads in a rectangular container. After validation, results are reported for a granular column of 9000 grains and ≈50 layers deep (at rest), agitated with a sinusoidal excitation with maximal acceleration 4.7g at 11.7 Hz. We report the evolution of density, granular temperature, and coordination number within a vibration cycle, and the effect of interstitial air on those parameters. In three-dimensional computer simulations we found that the presence of interstitial air can promote the collective motion of the granular material as a whole.

Original language	English
Article number	051301
Journal	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
Volume	79
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevE.79.051301
State	Published - May 6 2009
Externally published	Yes

ASJC Scopus Subject Areas

Condensed Matter Physics
Statistical and Nonlinear Physics
Statistics and Probability

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10.1103/PhysRevE.79.051301

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abstract = "We present a numerical study of the effect of interstitial air on a vertically vibrated granular bed within one period of oscillation. We use a three-dimensional molecular-dynamics simulation including air phenomenologically. The simulations are validated with experiments made with spherical glass beads in a rectangular container. After validation, results are reported for a granular column of 9000 grains and ≈50 layers deep (at rest), agitated with a sinusoidal excitation with maximal acceleration 4.7g at 11.7 Hz. We report the evolution of density, granular temperature, and coordination number within a vibration cycle, and the effect of interstitial air on those parameters. In three-dimensional computer simulations we found that the presence of interstitial air can promote the collective motion of the granular material as a whole.",

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AU - Idler, V.

AU - Sánchez, I.

AU - Paredes, R.

AU - Gutiérrez, G.

AU - Reyes, L. I.

AU - Botet, R.

PY - 2009/5/6

Y1 - 2009/5/6

N2 - We present a numerical study of the effect of interstitial air on a vertically vibrated granular bed within one period of oscillation. We use a three-dimensional molecular-dynamics simulation including air phenomenologically. The simulations are validated with experiments made with spherical glass beads in a rectangular container. After validation, results are reported for a granular column of 9000 grains and ≈50 layers deep (at rest), agitated with a sinusoidal excitation with maximal acceleration 4.7g at 11.7 Hz. We report the evolution of density, granular temperature, and coordination number within a vibration cycle, and the effect of interstitial air on those parameters. In three-dimensional computer simulations we found that the presence of interstitial air can promote the collective motion of the granular material as a whole.

AB - We present a numerical study of the effect of interstitial air on a vertically vibrated granular bed within one period of oscillation. We use a three-dimensional molecular-dynamics simulation including air phenomenologically. The simulations are validated with experiments made with spherical glass beads in a rectangular container. After validation, results are reported for a granular column of 9000 grains and ≈50 layers deep (at rest), agitated with a sinusoidal excitation with maximal acceleration 4.7g at 11.7 Hz. We report the evolution of density, granular temperature, and coordination number within a vibration cycle, and the effect of interstitial air on those parameters. In three-dimensional computer simulations we found that the presence of interstitial air can promote the collective motion of the granular material as a whole.

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Three-dimensional simulations of a vertically vibrated granular bed including interstitial air

Abstract

ASJC Scopus Subject Areas

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