General representations of polynomial elastic fields

Min Zhong Wang; Bai Xiang Xu; Ying Tao Zhao

doi:10.1115/1.4005556

General representations of polynomial elastic fields

Min Zhong Wang^*, Bai Xiang Xu, Ying Tao Zhao

^*Corresponding author for this work

School of Aerospace Engineering

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

8 Citations (Scopus)

Abstract

For hybrid finite elements based, for example, on complementary energy functional, polynomial trial functions of stress fields are required. Systematic schemes are given for the 2D and 3D elasticity, respectively. For 2D problems, the paper shows that there are maximal four independent polynomials for the nth order homogeneous polynomial Airy stress functions: two for the first order, three for the second order, and four for the nth order (n not less than 3). For 3D problems, there are 3(2n+1) independent polynomials for the nth order homogeneous polynomial displacement. The corresponding stress field can be given directly. As examples, explicit expressions of the corresponding independent polynomials are listed: up to the tenth order for the 2D case and up to the third order for the 3D case.

Original language	English
Article number	021017
Journal	Journal of Applied Mechanics, Transactions ASME
Volume	79
Issue number	2
DOIs	https://doi.org/10.1115/1.4005556
Publication status	Published - 2012

Keywords

elasticity
finite element trial function
harmonic polynomial
polynomial Airy stress function
polynomial elastic field

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10.1115/1.4005556

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AU - Wang, Min Zhong

AU - Xu, Bai Xiang

AU - Zhao, Ying Tao

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AB - For hybrid finite elements based, for example, on complementary energy functional, polynomial trial functions of stress fields are required. Systematic schemes are given for the 2D and 3D elasticity, respectively. For 2D problems, the paper shows that there are maximal four independent polynomials for the nth order homogeneous polynomial Airy stress functions: two for the first order, three for the second order, and four for the nth order (n not less than 3). For 3D problems, there are 3(2n+1) independent polynomials for the nth order homogeneous polynomial displacement. The corresponding stress field can be given directly. As examples, explicit expressions of the corresponding independent polynomials are listed: up to the tenth order for the 2D case and up to the third order for the 3D case.

KW - elasticity

KW - finite element trial function

KW - harmonic polynomial

KW - polynomial Airy stress function

KW - polynomial elastic field

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General representations of polynomial elastic fields

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