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Performance of a Piezoelectric Bimorph Harvester with Variable Width

Published online by Cambridge University Press:  05 May 2011

H. P. Hu*
Affiliation:
Department of Mechanics & School of Mechanical Science and Engineering, Huazhong University of Science and Technology, Wuhan, 430074, China
Z. J. Cui*
Affiliation:
Department of Mechanics, Huazhong University of Science and Technology, Wuhan, 430074, China School of Natural Resources and Oil Engineering, Xi 'an Oil University, Xi'an, 710065, China
J. G. Cao*
Affiliation:
Department of Mechanics, Huazhong University of Science and Technology, Wuhan, 430074, China
*
*Postdoctoral Researcher
**Associate Professor
**Associate Professor
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Abstract

This article analyzes the performance of a piezoelectric energy harvester in the flexural mode for scavenging ambient vibration energy. The energy harvester consists of a piezoelectric bimorph plate with a variable width. A theoretical study is performed and the computational results show that the output power density increases initially, reaches a maximum, and then decreases monotonically with the increasing width, underscoring the importance for the width design of the scavenging structure. Further analysis indicates that the peak of output power density is determined by both the bimorph deformation amplitude and the efficiency in scavenging-energy. The analysis for this simplified model piezoelectric harvester provides a framework for further development on design guidelines for piezoelectric energy harvesters of optimal performance.

Type
Articles
Copyright
Copyright © The Society of Theoretical and Applied Mechanics, R.O.C. 2007

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References

1.Roundy, S., P, W. P, W. and Rabaey, J., “A Study of Low Lever Vibrations as a Power Source for Wireless Sensor Nodes,” Computer Communications, 26, pp. 11311144 (2003).CrossRefGoogle Scholar
2.Yang, J. S., “A Thickness-Shear High Voltage Piezoelectric Transformer,” Int. J. Applied Electro Magnetics and Mechanics 10, pp. 105121 (1999).Google Scholar
3.Yang, J. S., “Extensional Vibration of a Nonuniform Piezoceramic Rod and High Voltage Generation,” Int. J. Applied Electromagnetics and Mechanics 16, pp. 2942 (2002).Google Scholar
4.Hu, Y. T., Zhang, X., Yang, J. S. and Jiang, Q., “Transmitting Electric Energy Through a Metal Wall by Acoustic Waves using Piezoelectric Transducers,” IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control, 50, pp. 773781 (2003).Google Scholar
5.Hu, Y. T., Chen, C. Y., Yang, X. H. and Du, Q. G., “Electric Energy Transmission Between Two Piezoelectric Transducers,” Acta Mechanica Solida Sinica 24, pp. 304312(2003).Google Scholar
6.Cho, Y. S., Pak, Y. E., Han, C. S. and Ha, S. K., “Five-Port Equivalent Electric Circuit of Piezoelectric Bimorph Beam,” Sensors and Actuators, 84, pp. 140148 (2000).Google Scholar
7.Ha, S. K., “Analysis of the Asymmetric Triple-Layered Piezoelectric Bimorph using Equivalent Circuit Models,” J. Acoustical Society of America 110, pp. 856 (2001).Google Scholar
8.Ottman, G. K., Hofmann, H. F., Bhatt, A. C. and Lesieutre, G. A., “Adaptive Piezoelectric Energy Harvesting Circuit for Wireless Remote Power Supply,” IEEE Trans. on Power Electronics 17, pp. 669676 (2002).CrossRefGoogle Scholar
9.Guyomar, D., Badel, A., Lefeuvre, E. and Richard, C., “Toward Energy Harvesting using Active Materials and Conversion Improvement by Nonlinear Processing,” IEEE Trans. on Ultrasonics, Ferroelectrics and Frequency Control, 52, pp. 584595 (2005).CrossRefGoogle ScholarPubMed
10.Shu, Y. C. and Lien, I. C., “Analysis of Power Output for Piezoelectric Energy Harvesting Systems,” Smart Materials and Structures, 15, pp. 14991512(2006).CrossRefGoogle Scholar
11.Shu, Y. C. and Lien, I. C., “Efficiency of Energy Conversion for a Piezoelectric Power Harvesting System,” J. Micromechanics and Microengineering, 16, pp. 24292438 (2006).Google Scholar
12.Yang, J., Zhou, H., Hu, Y. and Jiang, Q., “Performance of a Piezoelectric Harvester in Thickness-Stretch Mode of a Plate,” IEEE Trans. on Ultrasonics, Ferroelectrics and Frequency Control 52, pp. 18721876(2005).Google Scholar
13.Jiang, S. N., Li, X. F., Guo, S. H. and Hu, Y. T., “Apiezoelectric Analysis of a Vibrating Ceramic Bimorph for Power Harvesting,” Smart Materials and Structures, 14, pp. 769774 (2005).Google Scholar
14.Yang, J., Chen, Z. and Hu, Y., “An Exact Analysis of a Rectangular Plate Piezoelectric Generator,” IEEE Trans, on Ultrasonics, Ferroelectrics and Frequency Control, 54, pp. 190195(2007).CrossRefGoogle ScholarPubMed
15.Chen, Z. G., Hu, Y. T. and Yang, J. S., “A Piezoelectric Generator Based on Torsional Modes for Power Harvesting from Angular Vibrations,” Applied Mathematics and Mechanics, 28, pp. 779784 (2007).Google Scholar
16.Jiang, S. N., Jiang, Q., Hu, Y. T. and Li, X. F., “Analysis of a Piezoelectric Ceramic Shell in Thickness-Shear Vibration as a Power Harvester,” Int. J. Applied Electromagnetics and Mechanics, 24, pp. 2531 (2006).Google Scholar
17.Jiang, S. N. and Hu, Y. T., “Analysis of a Piezoelectric Bimorph Plate with a Central-Attached Mass as an Energy Harvester,” IEEE Trans. on Ultrasonics, Ferroelectrics and Frequency Control, 54, pp. 14631469 (2007).CrossRefGoogle ScholarPubMed
18.Hu, Y. T., Hu, H. P. and Yang, J. S., “A Low Frequency Piezoelectric Power Harvester Using a Spiral-Shaped Bimorph,” Science in China Series G, 49, pp. 649659 (2006).Google Scholar
19.Hu, H. P., Hu, Y. T. and Xue, H., “A Spiral-Shaped Harvester with an Improved Harvesting Element and an Adap tive Storage Circuit,” IEEE Trans. on Ultrasonics, Ferroelectrics and Frequency Control, 54, pp. 11771187(2007).Google Scholar
20.Hu, Y. T., Xue, H., Yang, J. S. and Jiang, Q., “Nonlinear Behavior of a Piezoelectric Power Harvester Near Resonance,” IEEE Trans. on Ultrasonics, Ferroelectrics and Frequency Control, 53, pp. 13871391 (2006).CrossRefGoogle ScholarPubMed
21.Yang, J. S. and Fang, H. Y., “Analysis of a Rotating Elastic Beam with Piezoelectric Films as Anangular Rate Sensor,” IEEE Trans. on Ultrasonics, Ferroelectrics and Frequency Control, 49, pp. 798804 (2002).Google Scholar
22. Standards Committee of the IEEE Ultrasonics, Ferroelectrics, A.F.C.S., IEEE Standard on Piezoelectricity (1987).Google Scholar
23.Wang, B. T., Chen, P. H. and Chen, R. L., “Finite Element Model Verification for the Use of Piezoelectric Sensor in Structural Modal Analysis,” Journal of Mechanics, 22, pp. 107114 (2006).Google Scholar
24.Wang, R. J., Handbook of Hydroacoustics Materials, Beijing, Scientific press (1981).Google Scholar
25.Ting, T. C., “Explicit Expression of the Stationary Values of Young's Modulus and the Shear Modulus for Anisotropic Elastic Materials,” Journal of Mechanics, 21, pp. 255266 (2005).CrossRefGoogle Scholar
26.Ting, T. C., “The Stationary Values of Young's Modulus for Monoclinic and Triclinic Materials,” Journal of Mechanics, 21, pp. 249253 (2005).Google Scholar
27.Holland, R. and EerNisse, E. P., Design of Resonant Pie zoelectric Devices Cambridge, MIT Press (1969).Google Scholar
28.Huo, Y. and Jiang, Q., “Effect of Polarization Switch Upon Stress in Thickness Vibration of a Ferroelectric Plate,” J. American Ceramic Society, 79, pp. 651654 (1996).Google Scholar