Evaluation of the effective elastic moduli of tetragonal fiber-reinforced composites based on Maxwell's concept of equivalent inhomogeneity

Sofia G. Mogilevskaya; Volodymyr I. Kushch; Henryk K. Stolarski; Steven L. Crouch

doi:10.1016/j.ijsolstr.2013.08.008

Evaluation of the effective elastic moduli of tetragonal fiber-reinforced composites based on Maxwell's concept of equivalent inhomogeneity

Sofia G. Mogilevskaya, Volodymyr I. Kushch, Henryk K. Stolarski, Steven L. Crouch

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

Maxwell's concept of an equivalent inhomogeneity is employed for evaluating the effective elastic properties of tetragonal, fiber-reinforced, unidirectional composites with isotropic phases. The microstructure induced anisotropic effective elastic properties of the material are obtained by comparing the far-field solutions for the problem of a finite cluster of isotropic, circular cylindrical fibers embedded in an infinite isotropic matrix with that for the problem of a single, tetragonal, circular cylindrical equivalent inhomogeneity embedded in the same isotropic matrix. The former solutions precisely account for the interactions between all fibers in the cluster and for their geometrical arrangement. The solutions to several example problems that involve periodic (square arrays) composites demonstrate that the approach adequately captures microstructure induced anisotropy of the materials and provides reasonably accurate estimates of their effective elastic properties.

Original language	English (US)
Pages (from-to)	4161-4172
Number of pages	12
Journal	International Journal of Solids and Structures
Volume	50
Issue number	25-26
DOIs	https://doi.org/10.1016/j.ijsolstr.2013.08.008
State	Published - Dec 2013

Bibliographical note

Funding Information:
The first author gratefully acknowledges support from the Theodore W. Bennett Chair, University of Minnesota. Appendix A

Keywords

Circular cylindrical fibers
Elastic moduli
Fourier series
Maxwell's methodology
Tetragonal fiber-reinforced composites

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Evaluation of the effective elastic moduli of tetragonal fiber-reinforced composites based on Maxwell's concept of equivalent inhomogeneity. / Mogilevskaya, Sofia G.; Kushch, Volodymyr I.; Stolarski, Henryk K. et al.
In: International Journal of Solids and Structures, Vol. 50, No. 25-26, 12.2013, p. 4161-4172.

Research output: Contribution to journal › Article › peer-review

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abstract = "Maxwell's concept of an equivalent inhomogeneity is employed for evaluating the effective elastic properties of tetragonal, fiber-reinforced, unidirectional composites with isotropic phases. The microstructure induced anisotropic effective elastic properties of the material are obtained by comparing the far-field solutions for the problem of a finite cluster of isotropic, circular cylindrical fibers embedded in an infinite isotropic matrix with that for the problem of a single, tetragonal, circular cylindrical equivalent inhomogeneity embedded in the same isotropic matrix. The former solutions precisely account for the interactions between all fibers in the cluster and for their geometrical arrangement. The solutions to several example problems that involve periodic (square arrays) composites demonstrate that the approach adequately captures microstructure induced anisotropy of the materials and provides reasonably accurate estimates of their effective elastic properties.",

keywords = "Circular cylindrical fibers, Elastic moduli, Fourier series, Maxwell's methodology, Tetragonal fiber-reinforced composites",

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AU - Mogilevskaya, Sofia G.

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AU - Stolarski, Henryk K.

AU - Crouch, Steven L.

N1 - Funding Information: The first author gratefully acknowledges support from the Theodore W. Bennett Chair, University of Minnesota. Appendix A

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N2 - Maxwell's concept of an equivalent inhomogeneity is employed for evaluating the effective elastic properties of tetragonal, fiber-reinforced, unidirectional composites with isotropic phases. The microstructure induced anisotropic effective elastic properties of the material are obtained by comparing the far-field solutions for the problem of a finite cluster of isotropic, circular cylindrical fibers embedded in an infinite isotropic matrix with that for the problem of a single, tetragonal, circular cylindrical equivalent inhomogeneity embedded in the same isotropic matrix. The former solutions precisely account for the interactions between all fibers in the cluster and for their geometrical arrangement. The solutions to several example problems that involve periodic (square arrays) composites demonstrate that the approach adequately captures microstructure induced anisotropy of the materials and provides reasonably accurate estimates of their effective elastic properties.

AB - Maxwell's concept of an equivalent inhomogeneity is employed for evaluating the effective elastic properties of tetragonal, fiber-reinforced, unidirectional composites with isotropic phases. The microstructure induced anisotropic effective elastic properties of the material are obtained by comparing the far-field solutions for the problem of a finite cluster of isotropic, circular cylindrical fibers embedded in an infinite isotropic matrix with that for the problem of a single, tetragonal, circular cylindrical equivalent inhomogeneity embedded in the same isotropic matrix. The former solutions precisely account for the interactions between all fibers in the cluster and for their geometrical arrangement. The solutions to several example problems that involve periodic (square arrays) composites demonstrate that the approach adequately captures microstructure induced anisotropy of the materials and provides reasonably accurate estimates of their effective elastic properties.

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KW - Elastic moduli

KW - Fourier series

KW - Maxwell's methodology

KW - Tetragonal fiber-reinforced composites

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Evaluation of the effective elastic moduli of tetragonal fiber-reinforced composites based on Maxwell's concept of equivalent inhomogeneity

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Bibliographical note

Keywords

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