Developments in large scale discrete element simulations with polyhedral particles

Lee, Seung Jae

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https://hdl.handle.net/2142/50542 Copy

Description

Title

Developments in large scale discrete element simulations with polyhedral particles

Author(s)

Lee, Seung Jae

Issue Date

2014-09-16

Director of Research (if dissertation) or Advisor (if thesis)

Hashash, Youssef M.

Doctoral Committee Chair(s)

Hashash, Youssef M.

Committee Member(s)

• Ghaboussi, Jamshid
• Tutumluer, Erol
• Olson, Scott M.

Department of Study

Civil & Environmental Eng

Discipline

Civil Engineering

Degree Granting Institution

University of Illinois at Urbana-Champaign

Degree Name

Ph.D.

Degree Level

Dissertation

Keyword(s)

• Discrete Element Method
• Granular Materials
• Geologic Materials
• Micromechanical Modeling
• Multiscale Modeling
• Polyhedral Particle Modeling
• Impulse-based Discrete Element Method

Abstract

Granular material is pervasive in our environment, and of significant importance in a number of science and engineering research fields. It is characterized by the complex macroscopic behavior, which originates from its discrete nature at the grain scale. Discrete Element Method (DEM) was proposed three decades ago to account for such discontinuity in the materials, and since then significant algorithmic developments have been made to enhance the performance of DEM. Nevertheless, DEM is still a computationally expensive method to simulate granular materials. This research focuses on the developments of novel computational methods and tools to conduct large scale discrete element simulations with realistic polyhedral particle modeling, aiming to provide a better insight into the underlying mechanisms of the granular materials and enhance the predictive capabilities for engineering applications. In this dissertation, the research effort is made in two different ways to (a) enhance the computational performance within the conventional DEM framework, and (b) develop a new method, impulse-based Discrete Element Method (iDEM). The developed methods are all implemented in a polyhedral DEM code, BLOKS3D, and the performance is quantified to demonstrate the significance of the works in terms of computational efficiency and simulation fidelity. The computational challenges and corresponding developments within the conventional DEM framework are first discussed with the details of modeling approaches to perform two series of polyhedral DEM simulations. The first study envisions the feasibility and viability of using polyhedral DEM approach for lunar regolith simulations, and the second study demonstrates the relative simplicity and reliability to capture the complex triaxial soil behavior with DEM. A new simulation method, iDEM, is then presented, which shows phenomenal speed-up by almost two orders of magnitude over the conventional DEM with reasonable levels of simulation fidelity. This method is formulated on features of the impulse-based dynamic simulation often employed in the computer graphics area where the emphasis is on code speed, numerical stability and physical plausibility. Contact force is not an integral part of the simulation, but required for engineering applications, thus retrieved with a proposed formulation. Therefore, the contact force is a by-product of the simulation that can be retrieved at any time if necessary.

Graduation Semester

2014-08

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http://hdl.handle.net/2142/50542

Copyright and License Information

Copyright 2014 by Seung Jae Lee

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