Advances in Computational Design

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Computational electromechanical approach for stability/instability of smart system actuated with piezoelectric NEMS

  • Luo, Zhonghua (School of Electronics and Information, Nanchang Institute of Technology) ;
  • Cheng, Xiaoling (School of Electronics and Information, Nanchang Institute of Technology) ;
  • Yang, Yuhan (School of Electronics and Information, Nanchang Institute of Technology)
  • Received : 2021.08.21
  • Accepted : 2022.03.08
  • Published : 2022.07.25
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Abstract

In this research, the size-dependent impact of an embedded piezoelectric nanoplate subjected to in-plane loading on free vibration characteristic is studied. The foundation is two-parameter viscoelastic. The nonlocal elasticity is employed in order to capture the influence of size of the plate. By utilizing Hamilton's principle as well as the first- order shear deformation theory, the governing equation and boundary conditions are achieved. Then, using Navier method the equations associated with the free vibration of a plate constructed piezoelectric material under in-plane loads are solved analytically. The presented formulation and solution procedure are validated using other papers. Also, the impacts of nonlocal parameter, mode number, constant of spring, electric potential, and geometry of the nanoplate on the vibrational frequency are examined. As this paper is the first research in which the vibration associated with piezoelectric nanoplate on the basis of FSDT and nonlocal elasticity is investigated analytically, this results can be used in future investigation in this area.

Keywords

Acknowledgement

1. Science and technology research project of Jiangxi Provincial Department of education, China, GJJ212104 2. Science and technology research project of Jiangxi Provincial Department of education, China, GJJ212105

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