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A novel scheme for imposing periodic boundary conditions on RVE in second-order computational homogenization for granular material

Xikui Li (The State Key Laboratory for Structural Analysis of Industrial Equipment, Dalian University of Technology, Dalian, Liaoning, China)
Songge Zhang (The State Key Laboratory for Structural Analysis of Industrial Equipment, Dalian University of Technology, Dalian, Liaoning, China)
Qinglin Duan (The State Key Laboratory for Structural Analysis of Industrial Equipment, Dalian University of Technology, Dalian, Liaoning, China)

Engineering Computations

ISSN: 0264-4401

Article publication date: 10 June 2019

Issue publication date: 15 October 2019

254

Abstract

Purpose

This paper aims to present a novel scheme for imposing periodic boundary conditions with downscaled macroscopic strain measures of gradient Cosserat continuum on the representative volume element (RVE) of discrete particle assembly in the frame of the second-order computational homogenization methods for granular materials.

Design/methodology/approach

The proposed scheme is based on the generalized Hill’s lemma of gradient Cosserat continuum and the incremental non-linear constitutive relation condensed to the peripheral particles of the RVE of discrete particle assembly. The generalized Hill’s lemma conducts to downscale the macroscopic strain or stress measures and to impose the periodic boundary conditions on the RVE boundary so that the Hill-Mandel energy equivalence condition is ensured. Because of the incremental non-linear constitutive relation condensed to the peripheral particles of the RVE, the periodic boundary displacement and traction constraints together with the downscaled macroscopic strains and strain gradients, micro-rotations and curvatures are imposed in the point-wise sense without the need of introducing the Lagrange multipliers for enforcing the periodic boundary displacement and traction constraints in a weak sense.

Findings

Numerical results demonstrate that the applicability and effectiveness of the proposed scheme in imposing the periodic boundary conditions on the RVE. The results of the RVE subjected to the periodic boundary conditions together with the displacement boundary conditions in the second-order computational homogenization for granular materials provide the desired estimations, which lie between the upper and the lower bounds provided by the displacement and the traction boundary conditions imposed on the RVE respectively.

Research limitations/implications

Each grain in the particulate system under consideration is assumed to be rigid and circular.

Practical implications

The proposed scheme for imposing periodic boundary conditions on the RVE can be adopted solely for estimating the effective mechanical properties of granular materials and/or integrated into the frame of the second-order computational homogenization method with a nested finite element method-discrete element method solution procedure for granular materials. It will tend to provide, at least theoretically, more reasonable results for effective material properties and solutions of a macroscopic boundary value problem simulated by the computational homogenization method.

Originality/value

This paper presents a novel scheme for imposing periodic boundary conditions with downscaled macroscopic strain measures of gradient Cosserat continuum on the RVE of discrete particle assembly for granular materials without need of introducing Lagrange multipliers for enforcing periodic boundary conditions in a weak (integration) sense.

Keywords

Acknowledgements

The authors are pleased to acknowledge the support of this work by the National Natural Science Foundation of China through contract/grant number 11372066.

Citation

Li, X., Zhang, S. and Duan, Q. (2019), "A novel scheme for imposing periodic boundary conditions on RVE in second-order computational homogenization for granular material", Engineering Computations, Vol. 36 No. 8, pp. 2835-2858. https://doi.org/10.1108/EC-10-2018-0480

Publisher

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Emerald Publishing Limited

Copyright © 2019, Emerald Publishing Limited

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