DEM simulation of bead motion during wet bead milling using an enlarged particle model

DEM simulation of bead motion during wet bead milling using an enlarged particle model

A new model, an enlarged particle model, is proposed for simulating behavior of numerous tiny beads in wet beads milling using discrete element method (DEM). The enlarged particle model is assumed to be composed of several tiny beads. The behavior of enlarged particles in the stirred mill was simula...

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Bibliographic Details
Published in:International journal of mineral processing Vol. 114-117; pp. 93 - 99
Main Authors: Yamamoto, Yasuhiro, Soda, Rikio, Kano, Junya, Saito, Fumio
Format: Journal Article
Language:English
Published: Elsevier B.V 21-11-2012
Subjects:
Bead mill
Discrete element method
Disperse
Enlarged particle
Enlarged particle
Discrete element method
Disperse
Bead mill
Online Access:Get full text
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Description
Summary:A new model, an enlarged particle model, is proposed for simulating behavior of numerous tiny beads in wet beads milling using discrete element method (DEM). The enlarged particle model is assumed to be composed of several tiny beads. The behavior of enlarged particles in the stirred mill was simulated numerically using DEM. Furthermore, an experiment measuring the bead velocity in a transparent milling chamber using a high-speed camera was conducted to validate the enlarged particle model. The behaviors of 2 and 3mm beads in the stirred mill were also simulated using DEM. The velocity distributions of beads obtained from the simulation agree well with experimental ones when choosing the adequate frictional coefficient of beads. Then the virtual frictional coefficient was introduced into the enlarged particle model. The virtual frictional coefficient was determined so that the velocity distribution of the enlarged particles agrees with the distribution obtained from experiments. The adequate virtual frictional coefficient increases with an increase in the enlarged ratio, which is determined as a volume ratio of enlarged particle to bead. The correlation between the adequate virtual frictional coefficient and the enlarged ratio was apparent. [Display omitted] ► An enlarged particle model is proposed for simulating tiny beads in bead mill. ► The enlarged particles agree with the distribution obtained from experiments. ► The enlarged ratio was correlated with the adequate virtual frictional coefficient.
ISSN:0301-7516
1879-3525
DOI:10.1016/j.minpro.2012.10.001