Serviceeinschränkungen vom 12.-22.02.2026 - weitere Infos auf der UB-Homepage
  • Multi-scale simulation of non-...

Treffer: Multi-scale simulation of non-linear cellular- and meta-materials with body-force-enhanced second-order homogenisation

Title:
Multi-scale simulation of non-linear cellular- and meta-materials with body-force-enhanced second-order homogenisation
Authors:
Wu, Ling, Segurado, Javier, Mustafa, Syed Mohib, Noels, Ludovic
Contributors:
A&M - Aérospatiale et Mécanique - ULiège
Source:
The 19th European Mechanics of Materials Conferences (EMMC19), Madrid, Spain [ES], 29-31 May 2024
Publication Year:
2024
Subject Terms:
Computational homogenisation, Second-order homogenisation, Cellular materials, Meta-materials, FE2, Plasticity, Engineering, computing & technology, Mechanical engineering, Ingénierie, informatique & technologie, Ingénierie mécanique
Document Type:
Konferenz conference paper not in proceedings<br />http://purl.org/coar/resource_type/c_18cp<br />conferencePaper<br />editorial reviewed
Language:
English
Relation:
info:eu-repo/grantAgreement/EC/H2020/862015
Access URL:
https://orbi.uliege.be/handle/2268/319369
Rights:
open access
http://purl.org/coar/access_right/c_abf2
info:eu-repo/semantics/openAccess
Accession Number:
edsorb.319369
Database:
ORBi

Weitere Informationen

editorial reviewed
Multi-scale simulation of lattices, cellular materials and meta-materials faces the difficulty of handling the local instabilities which correspond to a change of the micro-structure morphology. On the one hand, first order computational homogenisation, which considers a classical continuum at the macro-scale, cannot capture localisation bands. On the other hand, second-order computational homogenisation, which considers a higher order continuum at the macro-scale, introduces a size effect with respect to the Representative Volume Element (RVE) size.By reformulating second-order computational homogenisation as an equivalent homogenised volume, non-uniform body forces arise at the micro-scale and act as a supplementary volume term over the RVE. Contrarily to the original uniform body forces resulting from an asymptotic homogenization [1], the devised non-uniform body forces arise from the Hill-Mandel condition and are expressed in terms of the micro-scale strain localization tensor, i.e. the relation between the micro-scale and macro-scale deformation gradients [1]. The consistency and accuracy of the approach are illustrated by simulating non-linear elastic meta-materials and elasto-plastic cellular materials under compressive loading. This project has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 862015.REFERENCES[1] V. Monchiet, N. Auffray, J. Yvonnet, Strain-gradient homogenization: A bridge between the asymptotic expansion and quadratic boundary condition methods, Mechanics of Materials 143 (2020) 103309.[2] L. Wu, S. M. Mustafa, J. Segurado and L. Noels. Second-order computational homogenisation enhanced with non-uniform body forces for non-linear cellular materials and metamaterials. Computer Methods in Applied Mechanics Engineering, 407: 115931, 2023.
MOAMMM - Multi-scale Optimisation for Additive Manufacturing of fatigue resistant shock-absorbing MetaMaterials
9. Industry, innovation and infrastructure