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http://dx.doi.org/10.12989/csm.2021.10.2.185

Frequency characteristics of a multiferroic Piezoelectric/LEMV/CFRP/Piezomagnetic composite hollow cylinder under the influence of rotation and hydrostatic stress  

Selvamani, R. (Department of Mathematics, Karunya Institute of Technology and Sciences)
Mahesh, S. (Department of Mathematics, Karunya Institute of Technology and Sciences)
Ebrahimi, F. (Department of Mechanical Engineering, Imam Khomieni International University)
Publication Information
Coupled systems mechanics / v.10, no.2, 2021 , pp. 185-198 More about this Journal
Abstract
An analytical model is consider to scrutinize axisymmetric wave propagation in multiferroic hollow cylinder with rotating and initial stressed forces, where a piezomagnetic (PM) material layer is bonded to a piezoelectric (PE) cylinder together by Linear elastic materials with voids. Both distinct material combos are taken into account. Three displacement potential functions are introduced to uncouple the equations of motion, electric and magnetic induction. The numerical calculations are carried out for the non-dimensional frequency by fixing wave number and thickness. The arrived outputs are plotted as the dispersion curves for different layers. The results obtained in this paper can offer significance to the application of PE/PM composite hollow cylinder via LEMV and CFRP layers for the acoustic wave and microwave technologies.
Keywords
multiferroic material; LEMV/CFRP; initial stressed; rotating cylinders; dispersion relation;
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