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Digital
Library of the European Council for Modelling and Simulation |
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Title: |
Discrete element modelling of cohesionless,
cohesive and bonded granular materials - from model conceptualisations
to industrial scale applications |
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Authors: |
Jin Y. Ooi |
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Published in:
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(2017).ECMS 2017 Proceedings
Edited by: Zita Zoltay
Paprika, Péter Horák, Kata Váradi, Péter Tamás Zwierczyk, Ágnes Vidovics-Dancs, János Péter Rádics European Council for Modeling and Simulation. doi:10.7148/2017 ISBN:
978-0-9932440-4-9/ ISBN:
978-0-9932440-5-6 (CD) 31st European Conference on Modelling and Simulation, Budapest, Hungary, May 23rd
– May 26th, 2017 |
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Citation
format: |
Jin
Y. Ooi (2017). Discrete element modelling
of cohesionless, cohesive and bonded granular
materials - from model conceptualisations to
industrial scale applications, ECMS 2017
Proceedings Edited by: Zita Zoltay
Paprika, Péter Horák, Kata Váradi, Péter Tamás Zwierczyk, Ágnes Vidovics-Dancs, János Péter Rádics European Council
for Modeling and Simulation. doi:
10.7148/2017-0007 |
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DOI: |
https://doi.org/10.7148/2017-0007 |
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Abstract: |
Handling
and processing of bulk granular materials is of major importance in many
industries including agriculture, chemical, food, pharmaceutical,
construction and mining. In recent decades, the Discrete Element Method (DEM)
is increasingly adopted for studying the complex behaviour
of granular materials and simulating the industrial processes in many
applications. DEM computes at individual particle interaction level and by
incorporating relevant inter-particle forces and coupling with hydrodynamic
forces of any surrounding fluid in particle-fluid systems, it provides
important insights into the particle level phenomena – this in turn inform
the bulk and industrial level processes. In
this keynote lecture, the developments of three DEM contact models to model:
a) free flowing cohesionless solids; b) cohesive
fine powders and c) cementitious materials are
described. In particular, the meso-scale approach
of modelling cohesive material is proposed using a visco-elasto-plastic frictional adhesive contact model
developed recently at the University of Edinburgh [1,2]. The cohesive model
reflects the physical phenomena of adhesive contact forces in fine cohesive
particles and accounts for both elastic and plastic contact deformation with
the adhesion being dependent on contact plasticity. Also a bonded contact
model based on the Timoshenko beam theory which can
be used to model concrete, rock and other deformable-breakable materials will
also be presented [3]. The
suitability of these contact models to predict real physical behaviours will be discussed. The scaling laws of the
contact model parameters to produce the same load-deformation behaviour invariant of the particle size used in the
simulations are presented [4,5]. Averaging (coarse-graining) technique based
on statistical mechanics [6]is applied to the DEM
particle data to provide important insights into the mobilizedstress
field during an industrial process. The studies demonstrate successfulapplications of DEM simulations of large scale applications using DEM models withappropriate scaling laws and material
characterization experiments. |
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