Maximizing energy transfer in vibrofluidized granular systems

C. R.K. Windows-Yule; A. D. Rosato; D. J. Parker; A. R. Thornton

doi:10.1103/PhysRevE.91.052203

Maximizing energy transfer in vibrofluidized granular systems

C. R.K. Windows-Yule, A. D. Rosato, D. J. Parker, A. R. Thornton

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

7 Citations (Scopus)

Abstract

Using discrete particle simulations validated by experimental data acquired using the positron emission particle tracking technique, we study the efficiency of energy transfer from a vibrating wall to a system of discrete, macroscopic particles. We demonstrate that even for a fixed input energy from the wall, energy conveyed to the granular system under excitation may vary significantly dependent on the frequency and amplitude of the driving oscillations. We investigate the manner in which the efficiency with which energy is transferred to the system depends on the system variables and determine the key control parameters governing the optimization of this energy transfer. A mechanism capable of explaining our results is proposed, and the implications of our findings in the research field of granular dynamics as well as their possible utilization in industrial applications are discussed.

Original language	English
Article number	052203
Number of pages	10
Journal	Physical Review E - Statistical, Nonlinear, and Soft Matter Physics
Volume	91
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevE.91.052203
Publication status	Published - 22 May 2015

ASJC Scopus subject areas

Statistical and Nonlinear Physics
Statistics and Probability
Condensed Matter Physics

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title = "Maximizing energy transfer in vibrofluidized granular systems",

abstract = "Using discrete particle simulations validated by experimental data acquired using the positron emission particle tracking technique, we study the efficiency of energy transfer from a vibrating wall to a system of discrete, macroscopic particles. We demonstrate that even for a fixed input energy from the wall, energy conveyed to the granular system under excitation may vary significantly dependent on the frequency and amplitude of the driving oscillations. We investigate the manner in which the efficiency with which energy is transferred to the system depends on the system variables and determine the key control parameters governing the optimization of this energy transfer. A mechanism capable of explaining our results is proposed, and the implications of our findings in the research field of granular dynamics as well as their possible utilization in industrial applications are discussed.",

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AU - Windows-Yule, C. R.K.

AU - Rosato, A. D.

AU - Parker, D. J.

AU - Thornton, A. R.

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AB - Using discrete particle simulations validated by experimental data acquired using the positron emission particle tracking technique, we study the efficiency of energy transfer from a vibrating wall to a system of discrete, macroscopic particles. We demonstrate that even for a fixed input energy from the wall, energy conveyed to the granular system under excitation may vary significantly dependent on the frequency and amplitude of the driving oscillations. We investigate the manner in which the efficiency with which energy is transferred to the system depends on the system variables and determine the key control parameters governing the optimization of this energy transfer. A mechanism capable of explaining our results is proposed, and the implications of our findings in the research field of granular dynamics as well as their possible utilization in industrial applications are discussed.

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Maximizing energy transfer in vibrofluidized granular systems

Abstract

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