Response analysis of undamped primary system subjected to base excitation with a dynamic vibration absorber integrated with a piezoelectric stack energy harvester

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DOI:

https://doi.org/10.15625/0866-7136/17948

Keywords:

dynamic vibration absorber, vibration energy harvesting

Abstract

Dynamic vibration absorber (DVA) integrated with a piezoelectric stack energy harvesting subjected to base excitation is introduced in this paper. The system of dynamic vibration absorber and piezoelectric stack energy harvesting system (DVA-PSEH) has two functions, the first is to reduce vibrations for the primary system, and the second is to convert a part of the vibrational energy into electricity through the piezoelectric effect. The mechanical and electrical responses of the electromechanical system are determined by the complex amplitude method, then the numerical simulations are carried out to investigate the characteristics of DVA-PSEH.

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References

A. Erturk and D. J. Inman. Piezoelectric energy harvesting. Wiley, (2011).

M. Goldfarb and N. Celanovic. Modeling piezoelectric stack actuators for control of micromanipulation. IEEE Control Systems, 17, (1997), pp. 69–79.

J. Feenstra, J. Granstrom, and H. Sodano. Energy harvesting through a backpack employing a mechanically amplified piezoelectric stack. Mechanical Systems and Signal Processing, 22, (2008), pp. 721–734.

F. Qian, T.-B. Xu, and L. Zuo. Design, optimization, modeling and testing of a piezoelectric footwear energy harvester. Energy Conversion and Management, 171, (2018), pp. 1352–1364.

X. Jiang, Y. Li, J. Li, J. Wang, and J. Yao. Piezoelectric energy harvesting from trafficinduced pavement vibrations. Journal of Renewable and Sustainable Energy, 6, (2014).

W. Hendrowati, H. L. Guntur, and I. N. Sutantra. Design, modeling and analysis of implementing a multilayer piezoelectric vibration energy harvesting mechanism in the vehicle suspension. Engineering, 04, (11), (2012), pp. 728–738.

T. Darabseh, D. Al-Yafeai, A.-H. I. Mourad, and F. Almaskari. Piezoelectric method-based harvested energy evaluation from car suspension system: Simulation and experimental study. Energy Science & Engineering, 9, (2020), pp. 417–433.

J. Wang, Z. Shi, H. Xiang, and G. Song. Modeling on energy harvesting from a railway system using piezoelectric transducers. Smart Materials and Structures, 24, (2015).

Y.-A. Lai, J.-Y. Kim, C.-S. W. Yang, and L.-L. Chung. A low-cost and efficient d33-mode piezoelectric tuned mass damper with simultaneously optimized electrical and mechanical tuning. Journal of Intelligent Material Systems and Structures, 32, (2020), pp. 678–696.

J. P. D. Hartog. Mechanical vibrations. New York: McGraw-Hill, (1956).

N. N. Linh. Series combination models of piezoelectric energy harvesters with spring and damper. In the 11th National Conference on Mechanics, Vol. 2. (in Vietnamese).

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Published

30-12-2022

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Research Article

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