Abstract
A multi-resolution rectangular shell element with membrane-bending based on the Kirchhoff-Love theory is proposed. The multi-resolution analysis (MRA) framework is formulated out of a mutually nesting displacement subspace sequence, whose basis functions are constructed of scaling and shifting on the element domain of basic node shape functions. The basic node shape functions are constructed from shifting to other three quadrants around a specific node of a basic element in one quadrant and joining the corresponding node shape functions of four elements at the specific node. The MRA endows the proposed element with the resolution level (RL) to adjust the element node number, thus modulating structural analysis accuracy accordingly. The node shape functions of Kronecker delta property make the treatment of element boundary condition quite convenient and enable the stiffness matrix and the loading column vectors of the proposed element to be automatically acquired through quadraturing around nodes in RL adjusting. As a result, the traditional 4-node rectangular shell element is a mono-resolution one and also a special case of the proposed element. The accuracy of a structural analysis is actually determined by the RL, not by the mesh. The simplicity and clarity of node shape function formulation with the Kronecker delta property, and the rational MRA enable the proposed element method to be implemented more rationally, easily and efficiently than the conventional mono-resolution rectangular shell element method or other corresponding MRA methods.
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The authors would like to thank the associate editor Prof Phillip and anonymous referees for their valuable comments which help to promote the academic quality of the initial manuscript. The authors also appreciate the financial support by the Open Foundation of Chongqing Key Laboratory of Geomechanics and Geoenvironment Protection (Logistical Engineering University) (No. GKLGGP 2013-02).
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Xia, Y., Liu, Y., Chen, S. et al. A Rectangular Shell Element Formulation with a New Multi-Resolution Analysis. Acta Mech. Solida Sin. 27, 612–625 (2014). https://doi.org/10.1016/S0894-9166(15)60006-4
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DOI: https://doi.org/10.1016/S0894-9166(15)60006-4