Vibration power generation is an important issue in development of renewable energy. If a vibration system with a maximum possible amplitude is designed, it can be advantageous in improving the vibration power generation efficiency. In this study, we propose a Duffing-type bi-stable vibration energy harvesting system that utilizes the stochastic resonance phenomenon, which can significantly expand the vibration amplitude. We designed the motion rail shape of the bistable vibration model using the Duffing function, and created a Duffing-type wave-shaped motion rail using an acrylic plate. An electromagnetic motor was installed in place of the four rotating wheels below the mass block that moves on the wave-shaped motion rail. When the mass block moves on the rail, it can output a voltage directly from the electromagnetic motor. To verify the performance of the proposed bi-stable vibration energy-harvesting system, a vibration experiment was conducted by combining a random excitation signal that simulates an actual natural environment and intentional periodic excitation signal. Using the experimental results, the stochastic resonance phenomenon and vibration power generation performance of the bi-stable vibration energy-harvesting system were investigated. The stochastic resonance phenomenon can be reliably generated using the bi-stable vibration system proposed in this study, and a large amplitude expansion effect can be obtained in the response vibration of the mass block. In addition, using random signals simulating the natural environment and periodic signals as stimulus signals, vibration experiments were conducted separately for two measurement cases: single excitation and joint excitation. The measurement results showed that under the same input excitation energy, the simultaneous excitation of the two signals generated 82.99% more power than that generated by separate excitation of the two signals. The generation of the stochastic resonance phenomenon by exciting two signals simultaneously has a significant effect on the improvement of the power generation efficiency of the bi-stable vibration energy harvesting system.
Published in | Engineering and Applied Sciences (Volume 8, Issue 1) |
DOI | 10.11648/j.eas.20230801.12 |
Page(s) | 5-15 |
Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
Copyright |
Copyright © The Author(s), 2023. Published by Science Publishing Group |
Bi-Stable Vibration System, Duffing Moving Model, Vibration Energy Harvesting, Stochastic Resonance, Vibration Measurement Experiment, Vibration Power Generation
[1] | Zhang, H., Corr, L. R., & Ma, T. (2018). Issues in vibration energy harvesting. Journal of Sound and Vibration, 421, 79-90. doi.org/10.1016/j.jsv.2018.01.057. |
[2] | Mohanty, A., Parida, S., Behera, R. K., & Roy, T.. (2019). Vibration energy harvesting: A review. Journal of Advanced Dielectrics, 9, 4. doi.org/10.1142/S2010135X19300019. |
[3] | Tang, L., Yang, Y., & Soh, C. K. (2010). Toward Broadband Vibration-based Energy Harvesting. Journal of Intelligent Material Systems and Structures, 21, 18. doi.org/10.1177/1045389X10390249. |
[4] | Roundy, S. (2005). On the Effectiveness of Vibration-based Energy Harvesting. Journal of Intelligent Material Systems and Structures, 16, 10. doi.org/10.1177/1045389X05054042. |
[5] | Moss, S. D., Payne, O. R., Hart, G. A., & Ung, C. (2015). Scaling and power density metrics of electromagnetic vibration energy harvesting devices. Smart Materials and Structures, 24, 023001. doi: 10.1088/0964-1726/24/2/023001. |
[6] | Shahbazi, Y. (2019). Smart Flat Membrane Sheet Vibration-Based Energy Harvesters. Journal of Solid Mechanics, 11, 1, 78-90. doi: 10.22034/JSM.2019.664219. |
[7] | Lallart, M., Anton, S. R., & Inman, D. J. (2010). Frequency Self-tuning Scheme for Broadband Vibration Energy Harvesting. Journal of Intelligent Material Systems and Structures, 21, 9. doi.org/10.1177/1045389X10369716. |
[8] | Kubba, A. E., & Jiang, K. (2014). Efficiency Enhancement of a Cantilever-Based Vibration Energy Harvester. Sensors, 14, 188-211. doi: 10.3390/s140100188. |
[9] | Dong, L., Grissom, M., & Fisher, F. T. (2015). Resonant frequency of mass-loaded membranes for vibration energy harvesting applications. Energy, 3, 3, 344-359. doi: 10.3934/energy.2015.3.344. |
[10] | Dai, X. (2016). An vibration energy harvester with broadband and frequency-doubling characteristics based on rotary pendulums. Sensors and Actuators A: Physical, 241, 161-168. doi.org/10.1016/j.sna.2016.02.004. |
[11] | Tao, K., Ding, G., Wang, P., Liu, Q., & Yang, Z. (2012). Design and Simulation of Fully Integrated Micro Electromagnetic Vibration Energy Harvester. Applied Mechanics and Materials, 152-154, 1087-1090. doi.org/10.4028/www.scientific.net/AMM.152-154.1087. |
[12] | Zayed, A. A. A., Assal, S. F. M., Nakano, K., Kaizuka, T., & El-Bab, A. M. R. F. (2019). Design Procedure and Experimental Verification of a Broadband Quad-Stable 2-DOF Vibration Energy Harvester. Sensors, 19, 2893. doi.org/10.3390/s19132893. |
[13] | Ramlan, R., Brennan, M. J., Mace, B. R., & Burrow, S. G. (2012). On the performance of a dual-mode non-linear vibration energy harvesting device. Journal of Intelligent Material Systems and Structures, 23 (13), 1423-1432. doi: 10.1177/1045389X12443017. |
[14] | Gammaitoni, L., Neri, I., & Vocca, H. (2009). Nonlinear oscillators for vibration energy harvesting. Applied Physics Letters, 94, 164102. doi: 10.1063/1.3120279. |
[15] | Gafforelli, G., Corigliano, A., Xu, R., & Kim, S. G. (2014). Experimental verification of a bridge-shaped, nonlinear vibration energy harvester. Applied Physics Letters, 105, 203901. doi: 10.1063/1.4902116. |
[16] | Liu, W. Q., Badel, A., Formosa, F., & Wu, Y. P. (2015). A new figure of merit for wideband vibration energy harvesters. Smart Materials and Structures, 24, 12. doi: 10.1088/0964-1726/24/12/125012. |
[17] | Yang, W., & Towfighian, S. (2017). A hybrid nonlinear vibration energy harvester. Mechanical Systems and Signal Processing, 90, 317-333. doi.org/10.1016/j.ymssp.2016.12.032. |
[18] | Kumar, A., Ali, S. F., & Arockiarajan, A. (2018). Exploring the benefits of an asymmetric monostable potential function in broadband vibration energy harvesting. Applied Physics Letters, 112, 233901. doi: 10.1063/1.5037733. |
[19] | Su, D., Nakano, K., Zheng, R., & Cartmell, M. P. (2014). Investigations of a Stiffness Tunable Nonlinear Vibrational Energy Harvester. International Journal of Structural Stability and Dynamics, 14, 8. doi: 10.1142/S0219455414400239. |
[20] | Zhang, G., & Hu, J. (2014). A Branched Beam-Based Vibration Energy Harvester. Journal of Electronic Materials, 43, 3912-3921. doi: 10.1007/s11664-014-3398-5. |
[21] | Zhou, S., Chen, W., Malakooti, D. H., Cao, J., & Inman, D. J. (2016). Design and modeling of a flexible longitudinal zigzag structure for enhanced vibration energy harvesting. Journal of Intelligent Material Systems and Structures, 1, 14. doi: 10.1177/1045389X16645862. |
[22] | Lee, H., Sharpes, N., Abdelmoula, H., Abdelkefi, A., & Priya, S. (2018). Higher power generation from torsion-dominant mode in a zigzag shaped two-dimensional energy harvester, Applied Energy, 216, 494-503. doi.org/10.1016/j.apenergy.2018.02.083. |
[23] | Sharpes, N., Abdelkefi, A., Abdelmoula, H., Kumar, P., Adler, J., & Priya, S. (2016). Mode shape combination in a two-dimensional vibration energy harvester through mass loading structural modification. Applied Physics Letters, 109, 033901. doi.org/10.1063/1.4958689. |
[24] | Ansari, M. H. & Karami, M. A. (2016). Modeling and experimental verification of a fan-folded vibration energy harvester for leadless pacemakers, Journal of Applied Physics, 119, 094506. doi.org/10.1063/1.4942882. |
[25] | Malaji, P. V., & Ali, S. F. (2017). Magneto-mechanically coupled electromagnetic harvesters for broadband energy harvesting. Applied Physics Letters, 111, 083901. doi.org/10.1063/1.4997297. |
[26] | Jiang, W. A., & Chen, L. Q. (2016). Stochastic averaging of energy harvesting systems. International Journal of Non-Linear Mechanics, 85, 174-187. doi.org/10.1016/j.ijnonlinmec.2016.07.002. |
[27] | Dykman, M. I., Luchinsky, D. G., Mannella, R., McClintock, P. V. E., Stein, N. D. & Stocks, N. G. (1993). Nonconventional Stochastic Resonance. Journal of Statistical Physics, 70, 479-499. doi.org/10.1007/BF01053983. |
[28] | Gammaitoni, L. (1999). Stochastic resonance. Review of Modern Physics, 70, 223. doi.org/10.1103/RevModPhys.70.223. |
[29] | Harne, R. L., & Wang, K. W. (2013). A review of the recent research on vibration energy harvesting via bistable systems. Smart Materials and Structures, 22, 2, 023001. doi: 10.1088/0964-1726/22/2/023001. |
[30] | Pellegrini, S. P., Tolou, N., Schenk, M., & Herder, J. L. (2013). Bistable vibration energy harvesters: A review. Journal of Intelligent Material Systems and Structures, 24 (11) 1303-1312. doi: 10.1177/1045389X12444940. |
[31] | Zheng, R., Nakano, K., Hu, H., Su, D., & Cartmell, M. P. (2014). An application of stochastic resonance for energy harvesting in a bistable vibrating system. Journal of Sound and Vibration, 333, 2568-2587. doi.org/10.1016/j.jsv.2014.01.020 |
[32] | Wang, K., Dai, X., Xiang, X., Ding, G., & Zhao, X. (2019). Optimal potential well for maximizing performance of bi-stable energy harvester. Applied Physics Letters, 115, 143904. doi: 10.1063/1.5095693. |
[33] | Ibrahim, A., Towfighian, S., & Younis, M. I. (2017). Dynamics of Transition Regime in Bistable Vibration Energy Harvesters. Journal of Vibration and Acoustics, 139, 051008. doi: 10.1115/1.4036503. |
[34] | Kumar, A., Sharma, A., Vaish, R., Kumar, R., & Jain, S. C. (2018). A numerical study on flexoelectric bistable energy harvester. Applied Physics A, 124, 483. doi.org/10.1007/s00339-018-1889-6 |
[35] | Leng, Y. G., Gao, Y. J., Tan, D., Fan, S. B., & Lai, Z. H. (2015). An elastic-support model for enhanced bistable piezoelectric energy harvesting from random vibrations. Journal of Applied Physics, 117, 064901. doi: 10.1063/1.4907763. |
[36] | Friswell, M. I., Ali, S. F., Bilgen, O., Adhikari, S., Lees, A. W., & Litak, G. (2012). Non-linear piezoelectric vibration energy harvesting from a vertical cantilever beam with tip mass. Journal of Intelligent Material Systems and Structures, 23 (13), 1505-1521. doi: 10.1177/1045389X12455722. |
[37] | Bilgen, O., Friswell, M. I., Ali, S. F., & Litak, G. (2015). Broadband Vibration Energy Harvesting from a Vertical Cantilever Piezocomposite Beam with Tip Mass. International Journal of Structural Stability and Dynamics, 15, 2, 1450038. doi: 10.1142/S0219455414500382. |
[38] | Lan, C. B., & Qin, W. Y. (2014). Energy harvesting from coherent resonance of horizontal vibration of beam excited by vertical base motion. Applied Physics Letters, 105, 113901. doi: 10.1063/1.4895921. |
[39] | Zhao, W., Wu, Q., Zhao, X., Nakano, K., & Zheng, R. (2020). Development of large-scale bistable motion system for energy harvesting by application of stochastic resonance. Journal of Sound and Vibration, 473, 115213. doi.org/10.1016/j.jsv.2020.115213. |
[40] | Guo, L., Zhao, W., Gomi, N., Guan, J., & Zhao, X. (2022). Development of an Opposed Mass-Spring Type Bi-Stable Vibration Energy Harvesting System Using Stochastic Resonance. International Journal of Mechanical Engineering and Applications, 10 (6): 123-134. doi: 10.11648/j.ijmea.20221006.11. |
[41] | Zhao, W., Zheng, R., Yin, X., Zhao, X., & Kimihiko, K. (2021). An Electromagnetic Energy Harvester of Large-Scale Bistable Motion by Application of Stochastic Resonance. Journal of Vibration and Acoustics, 144, 011007. doi: 10.1115/1.4051265. |
[42] | Guo, L., Zhao, W., Guan, J., Gomi, N., & Zhao, X. (2022). Horizontal Bi-Stable Vibration Energy Harvesting Using Electromagnetic Induction and Power Generation Efficiency Improvement via Stochastic Resonance. Machines, 10, 899. doi.org/10.3390/machines10100899. |
APA Style
Xuguang Zhang, Wei Zhao, Jingchao Guan, Apollo B. Fukuchi, Xilu Zhao. (2023). Development of Bi-Stable Vibration Energy Harvesting System Using Duffing-Type Motion Model. Engineering and Applied Sciences, 8(1), 5-15. https://doi.org/10.11648/j.eas.20230801.12
ACS Style
Xuguang Zhang; Wei Zhao; Jingchao Guan; Apollo B. Fukuchi; Xilu Zhao. Development of Bi-Stable Vibration Energy Harvesting System Using Duffing-Type Motion Model. Eng. Appl. Sci. 2023, 8(1), 5-15. doi: 10.11648/j.eas.20230801.12
AMA Style
Xuguang Zhang, Wei Zhao, Jingchao Guan, Apollo B. Fukuchi, Xilu Zhao. Development of Bi-Stable Vibration Energy Harvesting System Using Duffing-Type Motion Model. Eng Appl Sci. 2023;8(1):5-15. doi: 10.11648/j.eas.20230801.12
@article{10.11648/j.eas.20230801.12, author = {Xuguang Zhang and Wei Zhao and Jingchao Guan and Apollo B. Fukuchi and Xilu Zhao}, title = {Development of Bi-Stable Vibration Energy Harvesting System Using Duffing-Type Motion Model}, journal = {Engineering and Applied Sciences}, volume = {8}, number = {1}, pages = {5-15}, doi = {10.11648/j.eas.20230801.12}, url = {https://doi.org/10.11648/j.eas.20230801.12}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.eas.20230801.12}, abstract = {Vibration power generation is an important issue in development of renewable energy. If a vibration system with a maximum possible amplitude is designed, it can be advantageous in improving the vibration power generation efficiency. In this study, we propose a Duffing-type bi-stable vibration energy harvesting system that utilizes the stochastic resonance phenomenon, which can significantly expand the vibration amplitude. We designed the motion rail shape of the bistable vibration model using the Duffing function, and created a Duffing-type wave-shaped motion rail using an acrylic plate. An electromagnetic motor was installed in place of the four rotating wheels below the mass block that moves on the wave-shaped motion rail. When the mass block moves on the rail, it can output a voltage directly from the electromagnetic motor. To verify the performance of the proposed bi-stable vibration energy-harvesting system, a vibration experiment was conducted by combining a random excitation signal that simulates an actual natural environment and intentional periodic excitation signal. Using the experimental results, the stochastic resonance phenomenon and vibration power generation performance of the bi-stable vibration energy-harvesting system were investigated. The stochastic resonance phenomenon can be reliably generated using the bi-stable vibration system proposed in this study, and a large amplitude expansion effect can be obtained in the response vibration of the mass block. In addition, using random signals simulating the natural environment and periodic signals as stimulus signals, vibration experiments were conducted separately for two measurement cases: single excitation and joint excitation. The measurement results showed that under the same input excitation energy, the simultaneous excitation of the two signals generated 82.99% more power than that generated by separate excitation of the two signals. The generation of the stochastic resonance phenomenon by exciting two signals simultaneously has a significant effect on the improvement of the power generation efficiency of the bi-stable vibration energy harvesting system.}, year = {2023} }
TY - JOUR T1 - Development of Bi-Stable Vibration Energy Harvesting System Using Duffing-Type Motion Model AU - Xuguang Zhang AU - Wei Zhao AU - Jingchao Guan AU - Apollo B. Fukuchi AU - Xilu Zhao Y1 - 2023/03/21 PY - 2023 N1 - https://doi.org/10.11648/j.eas.20230801.12 DO - 10.11648/j.eas.20230801.12 T2 - Engineering and Applied Sciences JF - Engineering and Applied Sciences JO - Engineering and Applied Sciences SP - 5 EP - 15 PB - Science Publishing Group SN - 2575-1468 UR - https://doi.org/10.11648/j.eas.20230801.12 AB - Vibration power generation is an important issue in development of renewable energy. If a vibration system with a maximum possible amplitude is designed, it can be advantageous in improving the vibration power generation efficiency. In this study, we propose a Duffing-type bi-stable vibration energy harvesting system that utilizes the stochastic resonance phenomenon, which can significantly expand the vibration amplitude. We designed the motion rail shape of the bistable vibration model using the Duffing function, and created a Duffing-type wave-shaped motion rail using an acrylic plate. An electromagnetic motor was installed in place of the four rotating wheels below the mass block that moves on the wave-shaped motion rail. When the mass block moves on the rail, it can output a voltage directly from the electromagnetic motor. To verify the performance of the proposed bi-stable vibration energy-harvesting system, a vibration experiment was conducted by combining a random excitation signal that simulates an actual natural environment and intentional periodic excitation signal. Using the experimental results, the stochastic resonance phenomenon and vibration power generation performance of the bi-stable vibration energy-harvesting system were investigated. The stochastic resonance phenomenon can be reliably generated using the bi-stable vibration system proposed in this study, and a large amplitude expansion effect can be obtained in the response vibration of the mass block. In addition, using random signals simulating the natural environment and periodic signals as stimulus signals, vibration experiments were conducted separately for two measurement cases: single excitation and joint excitation. The measurement results showed that under the same input excitation energy, the simultaneous excitation of the two signals generated 82.99% more power than that generated by separate excitation of the two signals. The generation of the stochastic resonance phenomenon by exciting two signals simultaneously has a significant effect on the improvement of the power generation efficiency of the bi-stable vibration energy harvesting system. VL - 8 IS - 1 ER -