准晶问题多项式应力函数及其在有限元中的应用

Yingtao Zhao; Yuwei Yang; Wei Zhang

doi:10.15918/j.tbit1001-0645.2023.156

准晶问题多项式应力函数及其在有限元中的应用

Translated title of the contribution: Polynomial Stress Functions of Quasicrystal Problems and Their Applications in FEM

Yingtao Zhao, Yuwei Yang, Wei Zhang

School of Aerospace Engineering

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

Abstract

In this paper, systematic approaches to determining polynomial stress functions for quasicrystal plane problems were presented based on the generalized Lekhnitskii’s anisotropic elasticity theory. The approaches were applied to develop hybrid stress function (HSF) finite elements. Results show that for quasicrystal plane problems, an arbitrary nth-degree homogeneous polynomial encompasses a maximum of six independent polynomials, and the general expression of the polynomial stress function can be explicitly expressed. The obtained polynomials are used as analytical trial functions to construct a novel 8-node hybrid stress function (HSF) element. In comparison with traditional numerical methods, HSF demonstrates higher accuracy and superior performance.

Translated title of the contribution	Polynomial Stress Functions of Quasicrystal Problems and Their Applications in FEM
Original language	Chinese (Traditional)
Pages (from-to)	887-894
Number of pages	8
Journal	Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology
Volume	44
Issue number	9
DOIs	https://doi.org/10.15918/j.tbit1001-0645.2023.156
Publication status	Published - Sept 2024

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10.15918/j.tbit1001-0645.2023.156

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title = "准晶问题多项式应力函数及其在有限元中的应用",

abstract = "In this paper, systematic approaches to determining polynomial stress functions for quasicrystal plane problems were presented based on the generalized Lekhnitskii{\textquoteright}s anisotropic elasticity theory. The approaches were applied to develop hybrid stress function (HSF) finite elements. Results show that for quasicrystal plane problems, an arbitrary nth-degree homogeneous polynomial encompasses a maximum of six independent polynomials, and the general expression of the polynomial stress function can be explicitly expressed. The obtained polynomials are used as analytical trial functions to construct a novel 8-node hybrid stress function (HSF) element. In comparison with traditional numerical methods, HSF demonstrates higher accuracy and superior performance.",

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AU - Yang, Yuwei

AU - Zhang, Wei

PY - 2024/9

Y1 - 2024/9

N2 - In this paper, systematic approaches to determining polynomial stress functions for quasicrystal plane problems were presented based on the generalized Lekhnitskii’s anisotropic elasticity theory. The approaches were applied to develop hybrid stress function (HSF) finite elements. Results show that for quasicrystal plane problems, an arbitrary nth-degree homogeneous polynomial encompasses a maximum of six independent polynomials, and the general expression of the polynomial stress function can be explicitly expressed. The obtained polynomials are used as analytical trial functions to construct a novel 8-node hybrid stress function (HSF) element. In comparison with traditional numerical methods, HSF demonstrates higher accuracy and superior performance.

AB - In this paper, systematic approaches to determining polynomial stress functions for quasicrystal plane problems were presented based on the generalized Lekhnitskii’s anisotropic elasticity theory. The approaches were applied to develop hybrid stress function (HSF) finite elements. Results show that for quasicrystal plane problems, an arbitrary nth-degree homogeneous polynomial encompasses a maximum of six independent polynomials, and the general expression of the polynomial stress function can be explicitly expressed. The obtained polynomials are used as analytical trial functions to construct a novel 8-node hybrid stress function (HSF) element. In comparison with traditional numerical methods, HSF demonstrates higher accuracy and superior performance.

KW - analytical trial function

KW - hybrid stress function(HSF) element

KW - polynomial stress function

KW - quasicrystal

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JO - Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology

JF - Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology

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ER -

准晶问题多项式应力函数及其在有限元中的应用

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