Limit state analysis of asymmetrical microstructures based on yield design computational homogenization approach-Reference-Cited by-同舟云学术

Limit state analysis of asymmetrical microstructures based on yield design computational homogenization approach

Published:2022-12-31 Issue:4 Volume:44 Page:526-537
ISSN:2815-5882
Container-title:Vietnam Journal of Mechanics
language:
Short-container-title:Vietnam J. Mech.

Author:

Ho Phuc L. H.^ORCID,Le Canh V.^ORCID,Nguyen Phuong H.^ORCID,Ngo Chanh T.

Abstract

This paper presents a novel formulation for the computational homogenization analysis of materials at the limit state. The polynomial interpolations are employed to impose the periodic boundary conditions for the fluctuating term of the displacement field when using arbitrary finite element meshes. Second-order cone programming provides an efficient solution to solve the resulting optimization problems, and accurate load multipliers can be obtained with the minimum computational cost. Several asymmetrical material models are investigated to perform the efficiency of the proposed method. The collapse mechanisms of the representative volume elements are also presented.

Publisher

Publishing House for Science and Technology, Vietnam Academy of Science and Technology (Publications)

Subject

General Medicine

Link

https://vjs.ac.vn/index.php/vjmech/article/download/17985/pdf

Reference14 articles.

1. J. C. Michel, H. Moulinec, and P. Suquet. Effective properties of composite materials with periodic microstructure: a computational approach. Computer Methods in Applied Mechanics and Engineering, 172, (1999), pp. 109–143.

2. V. Kouznetsova, W. A. M. Brekelmans, and F. P. T. Baaijens. An approach to micromacro modeling of heterogeneous materials. Computational Mechanics, 27, (2001), pp. 37–48.

3. C. Miehe and A. Koch. Computational micro-to-macro transitions of discretized microstructures undergoing small strains. Archive of Applied Mechanics (Ingenieur Archiv), 72, (2002), pp. 300–317.

4. M. G. D. Geers, V. G. Kouznetsova, and W. A. M. Brekelmans. Multi-scale computational homogenization: Trends and challenges. Journal of Computational and Applied Mathematics, 234, (2010), pp. 2175–2182.

5. K. Terada, M. Hori, T. Kyoya, and N. Kikuchi. Simulation of the multi-scale convergence in computational homogenization approaches. International Journal of Solids and Structures, 37, (2000), pp. 2285–2311.