Vibration of multilayer cantilever beams towards piezoelectric power harvesters

  • Affiliations:

    Hanoi University of Mining and Geology, Hanoi, Vietnam

  • *Corresponding:
    This email address is being protected from spambots. You need JavaScript enabled to view it.
  • Received: 15th-Nov-2023
  • Revised: 16th-Mar-2024
  • Accepted: 19th-July-2024
  • Online: 1st-Aug-2024
Pages: 89 - 97
Views: 524
Downloads: 3
Rating: , Total rating: 0
Yours rating

Abstract:

This paper investigates the vibration characteristics of a commonly employed mechanical structure, the cantilever beam, concerning its potential for direct electricity harvesting from piezoelectric crystals. Piezoelectric materials are renowned for their ability to generate electric charges when subjected to mechanical stress. To ensure continuous current generation, these materials require sustained excitation by external forces, typically achieved through vibration. However, piezoelectric crystals lack sufficient elasticity, necessitating attachment to a structurally conducive and easily vibratable framework. The cantilever beam, renowned for its simplicity and widespread use, serves as an ideal platform for this purpose. Layers of piezoelectric material (PZT5H) are affixed to brass-based cantilever beams to create various multilayer configurations. External forces are then applied at the free end of the beam to induce vibration. Given that the harvested power from PZT5H crystals correlates with the mechanical stress they experience, achieving optimal deformation is paramount. This is accomplished by leveraging the resonance effect of vibration, wherein the vibration modes and natural frequencies of the multilayer PZT5H beams must be thoroughly characterized. To this end, numerical methods and Finite Element Analysis via Abaqus software are employed. The vibrations of the brass base layer, as well as single-sided and double-sided PZT5H beams, are analyzed across four distinct mode shapes and corresponding natural frequencies. The study culminates in a comprehensive examination of the relationship between natural frequencies and dimensional parameters of the beams. Ultimately, this research offers valuable insights into the vibration behavior of cantilever beams, laying the groundwork for the development of efficient power harvesting devices utilizing mechanical vibration sources or tailored to specific applications.

How to Cite
Doan, L.Cong and Doan, G.Van 2024. Vibration of multilayer cantilever beams towards piezoelectric power harvesters. Journal of Mining and Earth Sciences. 65, 4 (Aug, 2024), 89-97. DOI:https://doi.org/10.46326/JMES.2024.65(4).09.
References

Ali, F., Raza, W., Li, X., Gul, H., and Kim, K.-H. (2019). Piezoelectric energy harvesters for biomedical applications. Nano Energy, 57, 879-902. https://doi.org/10.1016/j.nanoen. 2019.01.012.

Delnavaz, A., Voix, J. J. (2014). Flexible piezoelectric energy harvesting from jaw movements. Smart Materials and Structures, 23(10), 105020, IOP Science.

Dineva, P., Gross, D., Müller, R., Rangelov, T., Dineva, P., Gross, D., Rangelov, T. (2014). Piezoelectric materials. Springer.

Ericka, M., Vasic, D., Costa, F., Poulin, G., and Tliba, S. (2005). Energy harvesting from vibration using a piezoelectric membrane. Journal de Physique IV (Proceedings).

Gurusharan, Shegunashi, G., Adarsh, P., and Gurunagendra, G. R. (2021). Influence of envelope and core angles on natural frequency of a cantilever beam - A finite element approach. Materials Today: Proceedings, 47, 2237-2240. https://doi.org/ 10.1016/j.matpr.2021.04.192.

Janphuang, P., Lockhart, R. A., Isarakorn, D., Henein, S., Briand, D., and de Rooij, (2014). Harvesting energy from a rotating gear using an AFM-like MEMS piezoelectric frequency up-converting energy harvester, Journal of Microelectromechanical System, 24(3), 742-754. IEEE.

Karami, M. A., Farmer, J. R., and Inman, D. J.  (2013). Parametrically excited nonlinear piezoelectric compact wind turbine, Journal of Renewable Energy, 50, 977-987. Elsevier.

Repetto, C. E., Roatta, A., and Welti, R. J. (2012). Forced vibrations of a cantilever beam. European Journal of Physics, 33(5), 1187. https://doi.org/10.1088/0143-0807/33/5/ 1187.

Roundy, S., Wright, P. K., and Rabaey, J. (2003). A study of low level vibrations as a power source for wireless sensor nodes, Journal of Computer Communication, 26(11), 1131-1144. Elsevier.

Sezer, N., and Koç, M. (2020). A Comprehensive Review on the State-of-the-Art of Piezoelectric Energy Harvesting. Nano Energy, 80, 1-25. https://doi.org/10.1016/ j.nanoen.2020.105567.

Sun, C., Shang, G., Wang, H. (2019). On piezoelectric energy harvesting from human motion, Journal of Power and Energy Engineering 7(1), 155-164.

Wang, D. A., and Ko, H. H. (2010). Piezoelectric energy harvesting from flow-induced vibration. Journal of Micromechanics and Microengineering, 20(2), 025019.

Wu, Y., Qiu, J., Zhou, S., Ji, H., Chen, Y., and Li, S. (2018). A piezoelectric spring pendulum oscillator used for multi-directional and ultra low frequency vibration energy harvesting, Journal of Applied Energy. 231, 600-614. Elsevier.

Other articles