Higher-order electroelastic modelling of piezoelectric cylindrical nanoshell on elastic matrix

作     者：Xiao-ping Huang Peng-fei Hu Mohammad Arefi Xiao-ping Huang;Peng-fei Hu;Mohammad Arefi

作者机构：College of Mechanical and Electrical EngineeringNanning UniversityNanning530000GuangxiChina School of Materials Science and EngineeringLuoyang Institute of TechnologyLuoyang471023HenanChina Department of Solid MechanicsFaculty of Mechanical EngineeringUniversity of KashanKashan87317-51167Iran 

出 版 物：《Defence Technology（防务技术）》 (Defence Technology)

年 卷 期：2022年第18卷第5期

页      面：781-796页

核心收录：

学科分类：08[工学] 080501[工学-材料物理与化学] 0805[工学-材料科学与工程（可授工学、理学学位）] 

基　　金：supported by the Research team project of Nanning University(2018KYTD03) the Science and Technology Planning Project of Yongning Zone of Nanning(20180205A) Henan Province Doctor Startup Fund of China under Grant No.2012BZ01 

主　　题：Higher-order shear deformation theory Electro-elastic bending Functionally graded materials Size-dependent analysis Nonlocal parameter Cylindrical nano shell 

摘      要：This paper develops electro-elastic relations of functionally graded cylindrical nanoshell integrated with intelligent layers subjected to multi-physics loads resting on elastic *** piezoelectric layers are actuated with external applied *** nanocore is assumed in-homogeneous in which the material properties are changed continuously and gradually along radial ***-order shear deformation theory is used for the description of kinematic relations and electric potential distribution is assumed as combination of a linear function along thickness direction to show applied voltage and a longitudinal ***-elastic size-dependent constitutive relations are developed based on nonlocal elasticity theory and generalized Hooke’s *** principle of virtual work is used to derive governing equations in terms of four functions along the axial and the radial directions and longitudinal electric potential *** numerical results including radial and longitudinal displacements are presented in terms of basic input parameters of the integrated cylindrical nanoshell such as initial electric potential,small scale parameter,length to radius ratio and two parameters of *** is concluded that both displacements are increased with an increase in small-scale parameter and a decrease in applied electric potential.