Evaluation of the FMBEM efficiency in the analysis of porous structures

Ptaszny, J.; Hatłas, Marcin

doi:10.1108/ec-12-2016-0436

Cited by 7 publications

(4 citation statements)

References 62 publications

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“…There are several common features in engineering materials that may cause additional issues connected with the inverse identification procedure: (a) reinforcing fibers may have anisotropic properties, (b) porosity present in the material is not constant and increases with increasing volume fraction of the reinforcement, (c) orientation distribution of the reinforcement is not strictly random but depends on manufacturing process and may vary from unidirectional to random, and (d) the interface between the matrix and the reinforcement is imperfect. Moreover, the directions for future research are connected with improving the efficiency of micromechanical models for non-spheroidal inclusions, for example, by applying boundary element methods [48,49], instead of FEM, during the numerical solution of equivalent inclusion problem or developing metamodels instead of using time-consuming micromechanical models.…”

Section: Discussionmentioning

confidence: 99%

Inverse Identification of Elastic Properties of Constituents of Discontinuously Reinforced Composites

Ogierman

2018

Materials

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This paper is devoted to determination of elastic properties of composite constituents by using an inverse identification procedure. The aim of the developed identification procedure is to compute the elastic constants of individual material phases on the basis of known properties of composite materials. The inverse problem of identification has been solved by combining an evolutionary algorithm with a micromechanical model. The paper also focuses on selection of a suitable micromechanical model for optimization which should ensure a compromise between accuracy and complexity. Two different cases have been studied: composite reinforced with short cylindrical fibers and composite reinforced with cubic particles. Moreover, Monte Carlo simulations have been carried out to expose a difference in outcome of identification which may occur when uncertain input data is considered. Obtained results show that identification is successful only when properties of composite materials with at least two different volume fractions of the reinforcement are known.

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Section: Discussionmentioning

confidence: 99%

Inverse Identification of Elastic Properties of Constituents of Discontinuously Reinforced Composites

Ogierman

2018

Materials

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“…Therefore, very often, the RVE is considered as a model for simplifying the geometrical features of the real microstructure to provide a reasonable computation time [ 5 , 6 ]. Various numerical methods can be used for the analysis of the RVE, like, for instance, the boundary element method (BEM) [ 7 , 8 , 9 , 10 ], or the fast Fourier transform-based method (FFT) [ 11 , 12 , 13 ]. However, the most frequently used is the finite element method (FEM), which has become a standard approach.…”

Section: Introductionmentioning

confidence: 99%

Determination of Local Strain Distribution at the Level of the Constituents of Particle Reinforced Composite: An Experimental and Numerical Study

Ogierman

Kokot

2020

Materials

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This paper is devoted to numerical and experimental investigation of the strain field at the level of the constituents of two-phase particle reinforced composite. The research aims to compare the strain distributions obtained experimentally with the results obtained by using a computational model based on the concept of the representative volume element. A digital image correlation method has been used for experimental determination of full-field strain. The numerical investigation was conducted by the finite element analysis of the representative volume element. Moreover, usage of the novel method of assessment of the speckle pattern applicability for the measurement of local fields by using the digital image correlation method has been proposed. In general, the obtained experimental and numerical results are in good agreement although some discrepancies between the results have been noticed and discussed.

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“…An analytical method can be applied only to simple models. Numerical homogenization (Buyrachenko, 2007;Fish, 2006;Zhodi and Wriggers, 2008) using the boundary element method (BEM) (Ptaszny and Hatłas, 2018) or the finite element method (FEM) (Qiang et al, 2018) on the other hand is a very efficient and popular method. The identification problem may deal with searching of desired material properties, shape or position of inclusions or voids in the structure.…”

Section: Introductionmentioning

confidence: 99%

Evolutionary identification of microstructure parameters in the thermoelastic porous material

Długosz¹,

Schlieter²

2020

Journal of Theoretical and Applied Mechanics

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The work is devoted to the identification of microstructure parameters of a porous body under thermal and mechanical loads. The goal of the identification is to determine the parameters of the microstructure on the basis of measurements of displacements and temperatures at the macro level. A two-scale 3D coupled thermomechanical model of porous aluminum is considered. The representative volume element (RVE) concept modeled with periodical boundary conditions is assumed. Boundary-value problems for RVEs (micro-scale) are solved by means of the finite element method (FEM). An evolutionary algorithm (EA) is used for the identification as the optimization technique.

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Evaluation of the FMBEM efficiency in the analysis of porous structures

Cited by 7 publications

References 62 publications

Inverse Identification of Elastic Properties of Constituents of Discontinuously Reinforced Composites

Inverse Identification of Elastic Properties of Constituents of Discontinuously Reinforced Composites

Determination of Local Strain Distribution at the Level of the Constituents of Particle Reinforced Composite: An Experimental and Numerical Study

Evolutionary identification of microstructure parameters in the thermoelastic porous material

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