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An Effective Approach for Optimal PZT Vibration Absorber Placement on Composite Structures

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DOI: 10.4236/mme.2013.31002    3,171 Downloads   6,530 Views   Citations

ABSTRACT

In this paper, an attempt is made to determine the electric potential that would be generated in the piezoelectric vibration absorber using finite element piezoelectric analysis to determine optimal locations for damping of the first mode. Optimal placement of piezoelectric vibration absorber for passive vibration control application of a cantilever composite plate is investigated. Finite element piezoelectric modal analysis is performed. Models based on placing piezoelectric vibration absorbers at five different locations on the surface of the plate and incorporating piezoelectric properties are built. Modal analysis is used to find the electric potential developed in the piezoelectric vibration absorber. The location that yields the highest amount of electric potential would naturally be the best location for the vibration absorber. First bending mode of the cantilever composite plate is aimed for damping. Results of the analysis are verified with an experimental testing of the composite plate with piezoelectric vibration absorber firmly attached to the plate on the most effective location. A good agreement is found between the analytical and experimental results. Further, a resistive shunt circuit is designed for the passive damping of the first mode and attached to the vibration absorber in which the electric potential developed would be dissipated as heat to obtain passive vibration compensation. The experiment also demonstrates that a damping of 6 percent is obtained in the first mode of vibration and a great amount of damping is achieved in the second and third modes as well.

 

Conflicts of Interest

The authors declare no conflicts of interest.

Cite this paper

S. Venna and Y. Lin, "An Effective Approach for Optimal PZT Vibration Absorber Placement on Composite Structures," Modern Mechanical Engineering, Vol. 3 No. 1, 2013, pp. 21-26. doi: 10.4236/mme.2013.31002.

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