8‐node hexahedral unsymmetric element with rotation degrees of freedom for modified couple stress elasticity

Shang, Yan; Li, Chenfeng; Jia, Ke

doi:10.1002/nme.6325

Cited by 17 publications

(9 citation statements)

References 49 publications

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“…In fact, it is equivalent to the hybrid stress element based on the Hellinger-Reissner variational principle. The other papers by Shang et al [2][3][4] have the same problem. The unsymmetric element method first proposed by Rajendran and Liew 5 has the unsymmetric stiffness matrix as its obvious characteristic while also the major disadvantage due to the need for more computer memory and computations.…”

mentioning

confidence: 80%

Comments on “4‐node unsymmetric quadrilateral membrane element with drilling DOFs insensitive to severe mesh‐distortion” by Yan Shang and Wengen Ouyang, International Journal for Numerical Methods in Engineering 2018; 113: 1589–1606

Huang

2021

Numerical Meth Engineering

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mentioning

confidence: 80%

Comments on “4‐node unsymmetric quadrilateral membrane element with drilling DOFs insensitive to severe mesh‐distortion” by Yan Shang and Wengen Ouyang, International Journal for Numerical Methods in Engineering 2018; 113: 1589–1606

Huang

2021

Numerical Meth Engineering

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“…Therefore, the displacement u in the previous equations can be determined using C 0 continuous interpolation functions. The commonly used C 0 20-node isoparametric interpolation appears to be a good choice for the present 20-node element, but can be further enriched by the nodal rotation DOFs through the 3D link interpolation scheme, 38 as follows:…”

Section: The Test Functionsmentioning

confidence: 99%

“…The unsymmetric FEM is essentially characteristic of independently or partially independently designing the element's test function and trial function. [37][38][39][40] In the present development, the C 1 requirement is satisfied in a weak sense by introducing an independent rotation field into the virtual work principle and using the penalty function method. Then, the element's test functions of the displacement, mechanical rotation and electric potential are formulated using the quadratic serendipity isoparametric interpolation function, from which the strain, curvature and electric field can be further derived.…”

Section: Introductionmentioning

confidence: 99%

Penalty hexahedral element formulation for flexoelectric solids based on consistent couple stress theory

Shang,

Deng,

Cen

et al. 2023

Numerical Meth Engineering

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This work proposes a penalty 20‐node hexahedral element for size‐dependent electromechanical analysis based on the consistent couple stress theory. The nodal rotation degrees of freedom (DOFs) are used to approximate the mechanical rotation, meeting the C1 requirement in a weak sense by using the penalty function method, and to effectively enhance the standard isoparametric interpolation for determining the displacement test function. The normalized stress functions that satisfy the relevant equilibrium equation and strain compatibility equation a priori are employed to formulate the stress trial function. Since the element has only three displacement, three rotation and the electric potential DOFs per node, it has relatively simple formulation and can be readily incorporated into the existing finite element program. Several benchmarks are examined and the results demonstrate that the new element has good numerical accuracy and captures the size dependence effectively. In addition, the influence of the micro‐inertia on electromechanical dynamic responses of flexoelectric solids at small scale are analyzed using the proposed element. It is shown that the nature frequency decreases with the increase of micro‐inertia and in general, the influences are more obvious on higher order modes.

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“…Over the past decades, tremendous efforts have been made to develop finite elements with concise formulation and satisfactory performance. But unfortunately, those existing works primarily focus on the membrane elements, [25][26][27][28][29][30][31] solid elements, [32][33][34][35][36] and plate bending elements. [37][38][39][40] The literatures regarding the shell elements, especially the ones which can be used for analysis of shells with complex geometries, are very limited.…”

Section: Introductionmentioning

confidence: 99%

“…The y-direction deflections at the load point A of the pinched cylinder (μm) The reference values are obtained using 200,000 hexahedral solid element 35. …”

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confidence: 99%

An efficient 4‐node facet shell element for the modified couple stress elasticity

Shang

Cen

et al. 2021

Numerical Meth Engineering

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This work proposes a simple but robust 4-node 24-DOF facet shell element for static analysis of small-scale thin shell structures. To accommodate the size effects, the modified couple stress theory is employed as the theoretical basis.The element is constructed via two main innovations. First, the trial functions that can a priori satisfy related governing differential equations are adopted as the basic functions for formulating the element interpolations. Second, the generalized conforming theory and the penalty function method are employed to meet the C 1 continuity requirement in weak sense for ensuring the computation convergence property. Several benchmarks of shells with different geometries are tested to assess the new facet shell element's capability. The numerical results reveal that the element can effectively simulate the size-dependent mechanical behaviors of small-scale thin shells, exhibiting satisfactory numerical accuracy and low susceptibility to mesh distortion. Moreover, as the shell element uses only six degrees of freedom per node, it can be incorporated into the commonly available finite element programs very readily.

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8‐node hexahedral unsymmetric element with rotation degrees of freedom for modified couple stress elasticity

Cited by 17 publications

References 49 publications

Comments on “4‐node unsymmetric quadrilateral membrane element with drilling DOFs insensitive to severe mesh‐distortion” by Yan Shang and Wengen Ouyang, International Journal for Numerical Methods in Engineering 2018; 113: 1589–1606

Comments on “4‐node unsymmetric quadrilateral membrane element with drilling DOFs insensitive to severe mesh‐distortion” by Yan Shang and Wengen Ouyang, International Journal for Numerical Methods in Engineering 2018; 113: 1589–1606

Penalty hexahedral element formulation for flexoelectric solids based on consistent couple stress theory

An efficient 4‐node facet shell element for the modified couple stress elasticity

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