Anisotropic strain gradient thermoelasticity for cellular structures : plate models, homogenization and isogeometric analysis

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@article{424ffae264c24618a6ede58840a2d925,
title = "Anisotropic strain gradient thermoelasticity for cellular structures : plate models, homogenization and isogeometric analysis",
abstract = "For three-dimensional cellular plate-like structures with a triangular (extruded lattice) microarchitecture, the article develops a pair of two-scale plate models relying on the anisotropic form of Mindlin’s strain gradient thermoelasticity theory. Accordingly, a computational homogenization method is proposed for determining the constitutive parameters of the related higher-order constitutive tensors. First, a Reissner–Mindlin plate model is derived by dimension reduction from a general framework of three-dimensional orthotropic strain gradient thermoelasticity and written as a variational formulation. An isogeometric conforming Galerkin method is formulated accordingly. Second, the plate model is modified in order to reduce the number of the constitutive strain gradient parameters. These steps are then repeated by following the kinematical assumptions of the Kirchhoff plate theory. Third, in order to see the cellular microarchitecture as a homogeneous three-dimensional material with classical modulae of transversal isotropy, classical computational homogenization is accomplished for determining the corresponding material parameters. Fourth, in order to see the cellular structures as two-dimensional plates, a non-classical homogenization procedure is proposed for the identification of the strain gradient modulae of the plate models. Finally, a set of numerical examples illustrates the reliability and efficiency of the resulting plate models in homogenizing cellular plate-like structures into strain gradient plate models capturing the bending size effects induced by the microarchitecture.",
keywords = "Cellular plates, Lattice microarchitecture, Strain gradient thermoelasticity, Reissner-Mindlin plate, Kirchhof plate, Size effects, Isogeometric analysis",
author = "Sergei Khakalo and Jarkko Niiranen",
year = "2020",
month = "1",
day = "1",
doi = "10.1016/j.jmps.2019.103728",
language = "English",
volume = "134",
journal = "JOURNAL OF THE MECHANICS AND PHYSICS OF SOLIDS",
issn = "0022-5096",
publisher = "Elsevier Limited",

}

RIS - Lataa

TY - JOUR

T1 - Anisotropic strain gradient thermoelasticity for cellular structures : plate models, homogenization and isogeometric analysis

AU - Khakalo, Sergei

AU - Niiranen, Jarkko

PY - 2020/1/1

Y1 - 2020/1/1

N2 - For three-dimensional cellular plate-like structures with a triangular (extruded lattice) microarchitecture, the article develops a pair of two-scale plate models relying on the anisotropic form of Mindlin’s strain gradient thermoelasticity theory. Accordingly, a computational homogenization method is proposed for determining the constitutive parameters of the related higher-order constitutive tensors. First, a Reissner–Mindlin plate model is derived by dimension reduction from a general framework of three-dimensional orthotropic strain gradient thermoelasticity and written as a variational formulation. An isogeometric conforming Galerkin method is formulated accordingly. Second, the plate model is modified in order to reduce the number of the constitutive strain gradient parameters. These steps are then repeated by following the kinematical assumptions of the Kirchhoff plate theory. Third, in order to see the cellular microarchitecture as a homogeneous three-dimensional material with classical modulae of transversal isotropy, classical computational homogenization is accomplished for determining the corresponding material parameters. Fourth, in order to see the cellular structures as two-dimensional plates, a non-classical homogenization procedure is proposed for the identification of the strain gradient modulae of the plate models. Finally, a set of numerical examples illustrates the reliability and efficiency of the resulting plate models in homogenizing cellular plate-like structures into strain gradient plate models capturing the bending size effects induced by the microarchitecture.

AB - For three-dimensional cellular plate-like structures with a triangular (extruded lattice) microarchitecture, the article develops a pair of two-scale plate models relying on the anisotropic form of Mindlin’s strain gradient thermoelasticity theory. Accordingly, a computational homogenization method is proposed for determining the constitutive parameters of the related higher-order constitutive tensors. First, a Reissner–Mindlin plate model is derived by dimension reduction from a general framework of three-dimensional orthotropic strain gradient thermoelasticity and written as a variational formulation. An isogeometric conforming Galerkin method is formulated accordingly. Second, the plate model is modified in order to reduce the number of the constitutive strain gradient parameters. These steps are then repeated by following the kinematical assumptions of the Kirchhoff plate theory. Third, in order to see the cellular microarchitecture as a homogeneous three-dimensional material with classical modulae of transversal isotropy, classical computational homogenization is accomplished for determining the corresponding material parameters. Fourth, in order to see the cellular structures as two-dimensional plates, a non-classical homogenization procedure is proposed for the identification of the strain gradient modulae of the plate models. Finally, a set of numerical examples illustrates the reliability and efficiency of the resulting plate models in homogenizing cellular plate-like structures into strain gradient plate models capturing the bending size effects induced by the microarchitecture.

KW - Cellular plates

KW - Lattice microarchitecture

KW - Strain gradient thermoelasticity

KW - Reissner-Mindlin plate

KW - Kirchhof plate

KW - Size effects

KW - Isogeometric analysis

UR - http://www.scopus.com/inward/record.url?scp=85073111009&partnerID=8YFLogxK

U2 - 10.1016/j.jmps.2019.103728

DO - 10.1016/j.jmps.2019.103728

M3 - Article

VL - 134

JO - JOURNAL OF THE MECHANICS AND PHYSICS OF SOLIDS

JF - JOURNAL OF THE MECHANICS AND PHYSICS OF SOLIDS

SN - 0022-5096

M1 - 103728

ER -

ID: 37043469