Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers
The modeling of vibration of piezoelectric cantilevers has often been based on passive cantilevers of a homogeneous material. Although piezoelectric cantilevers and passive cantilevers share certain characteristics, this method has caused confusion in incorporating the piezoelectric moment into the...
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sg-ntu-dr.10356-1016012023-03-04T17:19:43Z Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers Yuan, Yanhui Du, Hejun Xia, Xin Wong, Yoke-Rung School of Mechanical and Aerospace Engineering DRNTU::Engineering::Mechanical engineering::Mechatronics The modeling of vibration of piezoelectric cantilevers has often been based on passive cantilevers of a homogeneous material. Although piezoelectric cantilevers and passive cantilevers share certain characteristics, this method has caused confusion in incorporating the piezoelectric moment into the differential equation of motion. The extended Hamilton's principle is a fundamental approach to modeling flexural vibration of multilayer piezoelectric cantilevers. Previous works demonstrated derivation of the differential equation of motion using this approach; however, proper analytical solutions were not reported. This was partly due to the fact that the differential equation derived by the extended Hamilton's principle is a boundary-value problem with nonhomogeneous boundary conditions which cannot be solved by modal analysis. In the present study, an analytical solution to the boundary-value problem was obtained by transforming it into a new problem with homogeneous boundary conditions. After the transformation, modal analysis was used to solve the new boundary-value problem. The analytical solutions for unimorphs and bimorphs were verified with three-dimensional finite element analysis (FEA). Deflection profiles and frequency response functions under voltage, uniform pressure and tip force were compared. Discrepancies between the analytical results and FEA results were within 3.5%. Following model validation, parametric studies were conducted to investigate the effects of thickness of electrodes and piezoelectric layers, and the piezoelectric coupling coefficient d 31 on the performance of piezoelectric cantilever actuators. Accepted version 2014-11-10T02:27:45Z 2019-12-06T20:41:11Z 2014-11-10T02:27:45Z 2019-12-06T20:41:11Z 2014 2014 Journal Article Yuan, Y., Du, H., Xia, X., & Wong, Y.-R. (2014). Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers. Smart materials and structures, 23(9), 095005-. https://hdl.handle.net/10356/101601 http://hdl.handle.net/10220/24200 10.1088/0964-1726/23/9/095005 en Smart materials and structures © 2014 IOP Publishing Ltd. This is the author created version of a work that has been peer reviewed and accepted for publication by Smart Materials and Structures, IOP Publishing Ltd. It incorporates referee’s comments but changes resulting from the publishing process, such as copyediting, structural formatting, may not be reflected in this document. The published version is available at: [http://dx.doi.org/10.1088/0964-1726/23/9/095005]. 15 p. application/pdf |
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DRNTU::Engineering::Mechanical engineering::Mechatronics Yuan, Yanhui Du, Hejun Xia, Xin Wong, Yoke-Rung Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers |
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The modeling of vibration of piezoelectric cantilevers has often been based on passive cantilevers of a homogeneous material. Although piezoelectric cantilevers and passive cantilevers share certain characteristics, this method has caused confusion in incorporating the piezoelectric moment into the differential equation of motion. The extended Hamilton's principle is a fundamental approach to modeling flexural vibration of multilayer piezoelectric cantilevers. Previous works demonstrated derivation of the differential equation of motion using this approach; however, proper analytical solutions were not reported. This was partly due to the fact that the differential equation derived by the extended Hamilton's principle is a boundary-value problem with nonhomogeneous boundary conditions which cannot be solved by modal analysis. In the present study, an analytical solution to the boundary-value problem was obtained by transforming it into a new problem with homogeneous boundary conditions. After the transformation, modal analysis was used to solve the new boundary-value problem. The analytical solutions for unimorphs and bimorphs were verified with three-dimensional finite element analysis (FEA). Deflection profiles and frequency response functions under voltage, uniform pressure and tip force were compared. Discrepancies between the analytical results and FEA results were within 3.5%. Following model validation, parametric studies were conducted to investigate the effects of thickness of electrodes and piezoelectric layers, and the piezoelectric coupling coefficient d 31 on the performance of piezoelectric cantilever actuators. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Yuan, Yanhui Du, Hejun Xia, Xin Wong, Yoke-Rung |
| format |
Article |
| author |
Yuan, Yanhui Du, Hejun Xia, Xin Wong, Yoke-Rung |
| author_sort |
Yuan, Yanhui |
| title |
Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers |
| title_short |
Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers |
| title_full |
Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers |
| title_fullStr |
Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers |
| title_full_unstemmed |
Analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers |
| title_sort |
analytical solutions to flexural vibration of slender piezoelectric multilayer cantilevers |
| publishDate |
2014 |
| url |
https://hdl.handle.net/10356/101601 http://hdl.handle.net/10220/24200 |
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1759853949005856768 |