Electromechanical coupling analysis of geometrically exact functionally graded piezoelectric shells based on weak form quadrature element method

Electromechanical coupling analysis of geometrically exact functionally graded piezoelectric shells based on weak form quadrature element method

In this study, a numerical model for electro-mechanical coupling analysis of geometrically nonlinear functionally graded piezoelectric shell is developed based on the weak form quadrature element method. Both piezoelectric and flexoelectric effects are introduced to establish the geometrically exact...

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Bibliographic Details
Published in:Archive of applied mechanics (1991) Vol. 94; no. 7; pp. 1923 - 1949
Main Authors: Chen, Tingrui, Liu, Jijun, Zhang, Run, Yao, Xiaohu
Format: Journal Article
Language:English
Published: Berlin/Heidelberg Springer Berlin Heidelberg 01-07-2024
Springer Nature B.V
Subjects:
Barium titanates
Classical Mechanics
Couplings
Effectiveness
Electric fields
Engineering
Functionally gradient materials
Nanoelectronics
Numerical models
Original
Piezoelectricity
Quadratures
Theoretical and Applied Mechanics
Thickness
Flexoelectric effect
Electro-mechanical coupling
Weak form quadrature element method
Functionally graded material
Geometrically exact shell
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Summary:In this study, a numerical model for electro-mechanical coupling analysis of geometrically nonlinear functionally graded piezoelectric shell is developed based on the weak form quadrature element method. Both piezoelectric and flexoelectric effects are introduced to establish the geometrically exact shell model with its constituent BaTiO 3 and PZT-5H graded through the thickness. The electric potentials are assumed quadratic along the shell thickness to introduce the electric field for numerical implementation, while four different closed- or open-circuit conditions are considered. Four typical examples are presented to demonstrate the effectiveness of the present model and illustrate the influences of electro-mechanical couplings and functional graded materials on the responses of shells undergoing large displacements and rotations. This model is a feasible scheme for studying complex nonlinear behaviors of piezoelectric shells that might be helpful in devising piezoelectric shell-based nanoelectronics.
ISSN:0939-1533
1432-0681
DOI:10.1007/s00419-024-02619-0