Assumed strain methods in micromechanics, laminate composite voxels and level sets

Lendvai, Jonas; Schneider, Matti

doi:10.1002/nme.7459

Numerical Meth Engineering

2024

DOI: 10.1002/nme.7459

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Assumed strain methods in micromechanics, laminate composite voxels and level sets

Jonas Lendvai,

Matti Schneider

Abstract: This work deals with the composite voxel method, which—in its original form—furnishes voxels containing more than one material with a surrogate material law accounting for the heterogeneity in the voxel. We show that the laminate composite voxel technique naturally arises as an assumed strain method, that is, the general framework introduced by Simo‐Rifai, for a specific choice of enhanced strain field. As a consequence, laminate composite voxels may be regarded as a kinematic assumption within a discretizatio… Show more

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2024

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Cited by 2 publications

References 137 publications

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FFT‐based computational micromechanics with Dirichlet boundary conditions on the rotated staggered grid

Risthaus,

Schneider

2024

Numerical Meth Engineering

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Imposing nonperiodic boundary conditions for unit cell analyses may be necessary for a number of reasons in applications, for example, for validation purposes and specific computational setups. The work at hand discusses a strategy for utilizing the powerful technology behind fast Fourier transform (FFT)‐based computational micromechanics—initially developed with periodic boundary conditions in mind—for essential boundary conditions in mechanics, as well, for the case of the discretization on a rotated staggered grid. Introduced by F. Willot into the community, the rotated staggered grid is presumably the most popular discretization, and was shown to be equivalent to underintegrated trilinear hexahedral elements. We leverage insights from previous work on the Moulinec–Suquet discretization, exploiting a finite‐strain preconditioner for small‐strain problems and utilize specific discrete sine and cosine transforms. We demonstrate the computational performance of the novel scheme by dedicated numerical experiments and compare displacement‐based methods to implementations on the deformation gradient.

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FFT‐based computational micromechanics with Dirichlet boundary conditions on the rotated staggered grid

Risthaus,

Schneider

2024

Numerical Meth Engineering

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Computing laminate composite voxel properties using Mirtich formulas

Lendvai,

Schneider

2024

Proc Appl Math and Mech

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Computational homogenization methods offer deeper insights into the mechanical behavior of heterogeneous materials, often exhibiting complex anisotropic properties due to intricate manufacturing processes. Micromechanical techniques exploit the knowledge of the material's microstructure to predict effective behavior. Digital material data, represented as voxels, require processing numerous image points. Despite the computational power of modern fast Fourier transform‐based numerical solvers, performance improvements are still valuable. The composite voxel technique, in its original form, furnishes voxels containing more than one material with a surrogate material law, resulting in higher accuracy. This work contributes to the understanding and application of composite voxels in computational micromechanics by integrating them into a level‐set‐based framework, providing a detailed methodology for deriving laminate composite properties using the formulas of Mirtich, and demonstrating their potential to enhance computational performance through a numerical example.

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Assumed strain methods in micromechanics, laminate composite voxels and level sets

Cited by 2 publications

References 137 publications

FFT‐based computational micromechanics with Dirichlet boundary conditions on the rotated staggered grid

FFT‐based computational micromechanics with Dirichlet boundary conditions on the rotated staggered grid

Computing laminate composite voxel properties using Mirtich formulas

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