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http://dx.doi.org/10.12989/sss.2016.18.2.249

Bimorph piezoelectric energy harvester structurally integrated on a trapezoidal plate  

Avsar, Ahmet Levent (Department of Aerospace Engineering, Middle East Technical University)
Sahin, Melin (Department of Aerospace Engineering, Middle East Technical University)
Publication Information
Smart Structures and Systems / v.18, no.2, 2016 , pp. 249-265 More about this Journal
Abstract
A bimorph piezoelectric energy harvester is developed for harvesting energy under the vortex induced vibration and it is integrated to a host structure of a trapezoidal plate without changing its passive dynamic properties. It is aimed to select trapezoidal plate as similar to a vertical fin-like structure which could be a part of an air vehicle. The designed energy harvester consists of an aluminum beam and two identical multi fiber composite (MFC) piezoelectric patches. In order to understand the dynamic characteristic of the trapezoidal plate, finite element analysis is performed and it is validated through an experimental study. The bimorph piezoelectric energy harvester is then integrated to the trapezoidal plate at the most convenient location with minimal structural displacement. The finite element model is constructed for the new combined structure in ANSYS Workbench 14.0 and the analyses performed on this particular model are then validated via experimental techniques. Finally, the energy harvesting performance of the bimorph piezoelectric energy harvester attached to the trapezoidal plate is also investigated through wind tunnel tests under the air load and the obtained results indicate that the system is a viable one for harvesting reasonable amount of energy.
Keywords
piezoelectric energy harvesting; finite element; experimental modal analysis; wind tunnel test;
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1 Abdelkefi, A. (2016), "Aeroelastic energy harvesting: A review", Int. J. Eng. Sci., 100, 112-135.   DOI
2 Advanced Linear Technology (2007), "EH300/EH301 EPAD(R) ENERGY HARVESTING Modules for low power applications", USA.
3 Akaydin, H.D., Elvin, N. and Andreopoulos, Y. (2013), "Chapter 10, flow induced vibrations for piezoelectric energy harvesting", (Eds., Niell Elvin and Alper Erturk), Advances in Energy Harvesting Methods, pp 241-267, Springer Science and Business Media, Newyork, USA.
4 Ali, M., Arafa, M. and Elaraby, M. (2013), "Harvesting energy from galloping oscillations", Proceedings of the World Congress on Engineering 2013 Vol III, WCE 2013, July 3 - 5, 2013, London, U.K.
5 Amoroso, F., Pecora, R., Ciminello, M. and Concilio, A. (2015), "An original device for train bogie energy harvesting: a real application scenario", Smart Struct. Syst., 16(3), 383-399.   DOI
6 ANSYS Workbench 14.0 Help Manual (2011).
7 Anton, S.R. (2011), "Multifunctional Piezoelectric Energy Harvesting Concepts", PhD Dissertation, University of Virginia Tech, USA.
8 APC International (2011), Piezoelectric Ceramics: Principles and Application (Paperback), Mackeyville, PA USA.
9 Arms, S.W., Townsend, C.P., Churchill, D.L., Galbreath, J.H., Corneau, B., Ketcham, R.P. and Phan, N. (2008), "Energy harvesting, wireless, structural health monitoring and reporting system", Proceedings of the 2nd Asia Pacific Workshop on SHM, Melbourne.
10 Available at: www.bksv.com/Products/transducers/vibration/accelerometers/accelerometers/4517.aspx (accessed in July 2015)
11 Available at: www.bksv.com/Products/transducers/vibration/impact-hammers/8206.aspx (accessed in July 2015).
12 Bae, J.S. and Inman, D.J. (2013), "Aeroelastic characteristics of linear and nonlinear piezo-aeroelastic energy harvester", J. Intel. Mat. Syst. Str., 1-16.
13 Bruel&Kjaer PULSE Software Help Manual (2014).
14 Bryant, M. and Garcia, E. (2011), "Modeling and testing of a novel aeroelastic flutter energy harvester", J. Vib. Acoust., 133, 011010 (11pp).   DOI
15 Dai, H L., Abdelkefi, A. and Wang, L. (2014), "Theoretical modeling and nonlinear analysis of piezoelectric energy harvesting from vortex-induced vibrations", J. Intel. Mat. Syst. Str., 1-14, doi:10.1177/1045389X14538329.
16 Dai, H.L., Abdelkefi, A. and Wang, L. (2014), "Piezoelectric energy harvesting from concurrent vortex-induced vibrations and base excitations", Nonlinear Dynam., 77, 967-981.   DOI
17 Erturk, A. (2011), Piezoelectric Energy Harvesting, John Wiley and Sons, West Sussex, United Kingdom
18 Erturk, A., Vieira, W.G.R., De Marqui, Jr., C. and Inman, D.J. (2010), "On the energy harvesting potential of piezoaeroelastic system", Appl. Phys. Lett., 96, 184103-1-184103-3.   DOI
19 Gao, X. (2011), "Vibration and Flow Energy Harvesting using Piezoelectric", PhD Dissertation, Drexel University, USA.
20 Hobeck, J.D. and Inman, D.J. (2012), "Artificial piezoelectric grass for energy harvesting from turbulence-induced vibration", Smart Mater. Struct., 21, 105024 (10pp).   DOI
21 Liu, H., Zhang, S., Kathiresan, R., Kobayashi, T. and Lee, C. (2012), "Development of piezoelectric microcantilever flow sensor with wind-driven energy harvesting capability", Appl. Phys. Lett., 100, 223905; doi: 10.1063/1.4723846   DOI
22 Hofmann, H. (2011), Power Electronic Circuits for Vibration-Based Energy Harvesting using Piezoelectric Devices. Available at: http://www.psma.com/sites/default/files/uploads/tech-forums-energyharvesting/presentations/2011-apec-sp-111-power-electronic-circuits-vibration-based-energy-harvesting-using-piezoelectric-dev.pdf (accessed in July 2015)
23 Kahraman, E. (2011) "Investigation of the Dynamic Properties of Trapezoidal Plates", MSc. Dissertation, METU, Turkey.
24 Koyvanich, K., Smithmaitrie, P. and Muensit, N. (2015), "Perspective microscale piezoelectric harvester for converting flow energy in water way", Adv. Mater. Lett., 6(6), 538-543.   DOI
25 Marqui Jr., C.D. and Erturk, A. (2012), "Electroaeroelastic analysis of airfoil-based wind energy harvesting using piezoelectric transduction and electromagnetic induction", J. Intel. Mat. Syst. Str., 24(7), 846-854.   DOI
26 Marqui Jr., C.D., Vieira, W.G.R., Erturk, A. and Inman, D.J. (2011), "Modeling and analysis of piezoelectric energy harvesting from aeroelastic vibrations using the doublet-lattice method", J. Vib. Acoust., 133, 011003-1 (9pp).   DOI
27 Mehmood, A., Abdelkefi, A., Hajj, M.R., Nayfeh, A.H., Akhtar, I. and Nuhait, A.O. (2013), "Piezoelectric energy harvesting from vortex-induced vibrations of circular cylinder", J. Sound Vib., 332, 4656-4667.   DOI
28 Mercan, B., Ostovan, Y., Dogan, E. and Uzol. O. (2010), "Effect of chordwise modulated waveform tip injection on the characteristics of the tip vortex", Proceedings of the 40th Fluid Dynamics Conference and Exhibit, Chicago, Illinois, USA
29 National Instrument Signal Express Software Help Manual (2014).
30 National Instrument Data Acquisition System Help Manual (2014).
31 Sarioglu, M. and Yavuz, T. (2000), "Vortex shedding from circular and rectangular cylinders place horizontally in a turbulent flow", Turk J. Engin. Environ. Sci., 24, 217-28.
32 Shan, X., Song, R., Liu, B. and Xie, T. (2015), "Novel energy harvesting: A macro fiber composite piezoelectric energy harvester in the water vortex", Ceramics Int., 41, 763-767.   DOI
33 Smart Material Corp (2012), Macro Fiber Composite - MFC.
34 Smart Material Corp. (2012), "Energy Harvester Development Kit", Germany.
35 Song, R., Shan, X., Lv, F., Li, J. and Xie, T. (2015), "A novel piezoelectric energy harvester using the macro fiber composite cantilever with a bicylinder in water", Appl. Sci., 5, 1942-1954.   DOI
36 Sousa, V.C., Anicezio, M.D.M., Marqui Jr., C.D. and Erturk, A. (2011), "Enhanced aeroelastic energy harvesting by exploiting combined nonlinearities: theory and experiment", Smart Mater. Struct., 20, 094007 (8pp).   DOI
37 Techet, A.H. (2010), "Vortex Induced Vibration- Lecture Notes", Massachusetts Institute of Technology, USA.
38 Wang, H., Tang, L., Shan, X., Xie, T. and Yang, Y. (2014), "Modeling and performance evaluation of a Piezoelectric Energy Harvester with segmented electrodes", Smart Struct. Syst., 14(2), 247-266.   DOI
39 Zhu, D. (2011), "Chapter 2: Vibration Energy Harvesting: Machinery Vibration, Human Movement and Flow Induced Vibration", www.intechopen.com.
40 Zhu, D., Beeby, S., Tudor, J., White, N. and Harris, N. (2010), "A novel miniature wind generator for wireless sensing applications", Proceedings of the IEEE Sensors 2010, ISBN 978-1-4244-8170-5, Waikoloa, Hawaii, USA.