Modeling of high-density compaction of granular materials by the Discrete Element Method

Harthong, Barthélémy; Jérier, Jean-François; Dorémus, P.; Imbault, D.; Donzé, Frédéric‐Victor

doi:10.1016/j.ijsolstr.2009.05.008

Cited by 131 publications

(94 citation statements)

References 20 publications

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“…Finally, Voronoi cells may be utilized to estimate particle volumes, resulting in a model similar to the one proposed by Harthong et al [13]. This would however increase the complexity of the DEM and particle number reduction might be necessary to maintain the computational cost within reasonable limits.…”

Section: Comparison Between Experimental and Numerical Studymentioning

confidence: 99%

“…However, compression of plastically deforming granules has been investigated by the FE/DE method [12]. In order to save computational time when simulating contact forces, the extraction of a contact expression from the FE/DE method has proven successful in DEM simulations [13]. In order to simulate more realistic systems, corresponding to experimental compressions, the combined FE/DE method is impracticable.…”

Section: Introductionmentioning

confidence: 99%

“…At higher relative densities, the contact deformation is dependent on the influence of neighbouring particles [14], which is not considered in the contact model. However, simulations at relative densities exceeding 0.8 are feasible using a contact law derived from a combined discrete and continuum model in which Voronoi cells are used to estimate particle volumes [13].…”

Section: Introductionmentioning

confidence: 99%

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An experimental evaluation of the accuracy to simulate granule bed compression using the discrete element method

Persson

Frenning

2012

Powder Technology

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PostprintThis is the accepted version of a paper published in Powder Technology. This paper has been peerreviewed but does not include the final publisher proof-corrections or journal pagination.Citation for the original published paper (version of record):Persson, A., Frenning, G. (2012) An experimental evaluation of the accuracy to simulate granule bed compression using the discrete element method. AbstractIn this work, granule compression is studied both experimentally and numerically with the overall objective of investigating the ability of the discrete element method (DEM) to accurately simulate confined granule bed compression. In the experiments, granules of microcrystalline cellulose (MCC) in the size range 200-710 µm were used as model material. Unconfined uniaxial compression of single granules was performed to determine granule properties such as the yield pressure and elastic modulus and compression profiles of the MCC granules were obtained from granule bed compression experiments. By utilizing the truncated Hertzian contact model for elastic-perfectly plastic materials, the rearrangement and plastic deformation stages of the force displacement curve were found to be in reasonable agreement with experiments. In an attempt to account for the final compression stage, elastic deformation of the compact, a simple modification of the contact model was proposed. This modification amounted to the introduction of a maximal plastic overlap, beyond which elastic deformation was the only deformation mode possible. Our results suggest that the proposed model provides an improved, although not perfect, 2 description of granule bed compression at high relative densities and hence may be used as a basis for future improvements.

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Section: Comparison Between Experimental and Numerical Studymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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An experimental evaluation of the accuracy to simulate granule bed compression using the discrete element method

Persson

Frenning

2012

Powder Technology

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“…Continuum deformable representation of ideal shapes using finite elements has been considered previously, particularly in powder technology (e.g. Harthong et al, 2009;Nezamabadi et al, 2015;Rathbone et al, 2015). The use of combined finite-discrete approaches to model systems of spheres is, however, not well established.…”

Section: Introductionmentioning

confidence: 99%

A micro finite-element model for soil behaviour: numerical validation

Nadimi

Fonseca

2018

Géotechnique

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This is the published version of the paper.This version of the publication may differ from the final published version. A micro finite-element (μFE) model capable of handling arbitrary shapes and deformable grains has been developed by the authors. The basis of this μFE model is to use a virtualised soil fabric obtained from micro computed tomography (μCT) of real sand to simulate grain-to-grain interaction in a framework of combined discrete-finite-element method. By incorporating grain deformation into the model, the contact response emerges from the interaction of contacting bodies and each irregular contact area will produce a unique response. A detailed numerical description of grain morphology and contact topology of a natural sand and the subsequent simulation are presented in the original paper. The present study focuses on the numerical validation of the constitutive contact behaviour against existent theories, for a single sphere and an assembly of spheres. The ability of the model to simulate elastic-plastic behaviour making use of the deformability of the grains is demonstrated. The unloading-reloading behaviour associated with the geometrical arrangement of the grains for a granular assembly under triaxial compression is examined in terms of energy dissipation quantities. Permanent repository link:

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“…Examples include: avalanches, segregation (which grains of different type separate under vibration), crystallization (when grains arrange into ordered configurations), pattern formation (when grains arrange into patterns, such as dunes or ripples) or jamming (when the flow of grains stops abruptly) [1]. Micromechanical analysis of compaction and particulate/granular materials has been of significance to academics and industrial communities, from beach sandcastles to chemical, pharmaceutical, food, mechanical, civil, mining and petroleum engineering as well as underground reservoir industry, and materials processing sectors [2][3][4][5][6][7][8][9][10][11][12][13][14][15]. Granular media are thermal, quite normal after all, usually with different particle-scale properties and inter-particle interactions, which are responsible for their complex behaviors at the low gravitational environment and macroscopic scale and difficult to assess experimentally [6,11,12,[16][17][18][19][20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Micromechanical Analysis of Compaction and Drilling of Granular Media- A Review

Okorie¹

2017

J Geol Geophys

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Granular matter is ubiquitous in our daily life yet far from completely understood. These granular materials have constituted a class of complex systems which exhibit global behaviors been reminiscent of solids, liquids, gases, or otherwise uniquely their own. The key to achieve good properties lies in the material structure from the molecules, via structures on nano and micro levels to the macroscopic material. This paper also reviewed selected approaches and models that have been developed for granular media prediction. However, development of new approaches at the micro and nano scales to sense the stress distribution characteristics of complex rock media, especially the grounds bearing petroleum resources of Nigeria has been of vital concern/importance to the area of petroleum drilling and exploration. By conducting such fundamental level research, development of highly efficient drilling processes with potentially much less energy inputs and minimizing the carbon blue prints is the best approach.

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Modeling of high-density compaction of granular materials by the Discrete Element Method

Cited by 131 publications

References 20 publications

An experimental evaluation of the accuracy to simulate granule bed compression using the discrete element method

An experimental evaluation of the accuracy to simulate granule bed compression using the discrete element method

A micro finite-element model for soil behaviour: numerical validation

Micromechanical Analysis of Compaction and Drilling of Granular Media- A Review

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