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Design and experimental study of rotary-type energy harvester

Narolia, T.; Gupta, V. K.; Parinov, I.

Journal of Intelligent Material Systems and Structures 31(13): 1594-1603

2020

ISSN/ISBN: 1045-389X
DOI: 10.1177/1045389x20930085
Accession: 082960340

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Summary
A rotary-type energy harvester for the applications having space restrictions has been designed and developed to harvest the energy from rotary motion system. The rotation kinetic energy is converted into electrical energy through a lead zirconate titanate patch, which is strained by magnetic force. Most of the researchers used d 31 mode of the piezoelectric material of such conversion. Some researchers have explored d 33 mode harvester with piezo patch along the circumferential direction. In this article, d 33 mode of harvesting with radial direction piezo patch has been proposed. Mathematical and finite element models are developed to calculate the harvested energy. The results are experimentally verified. The average output power of 14.48 nW is generated corresponding to the magnetic force of 0.3126 N and rotational speed of 2100 r/min. The results from the mathematical and finite element models are observed to be consistent with the experimental results. Such harvester will be useful for the applications having space limitations such as self-power generation in an artillery shell and rotary projectile.

References

Hou, C.; Shan, X.; Dang, S.; Du, X.; Sui, G.; Xie, T. 2025: A magnetically excited broadband rotary piezoelectric energy harvester with nonlinear energy sink: Theoretical investigations and experimental Verifications Mechanical Systems and Signal Processing 224: 112085
Khameneifar, F.; Arzanpour, S.; Moallem, M. 2013: A Piezoelectric Energy Harvester for Rotary Motion Applications: Design and Experiments IEEE/ASME Transactions on Mechatronics 18(5): 1527-1534
Pan, C.; Chen, Y.; Liu, Z.; Huang, C. 2013: Design and fabrication of LTCC electro-magnetic energy harvester for low rotary speed Sensors and Actuators A: Physical 191: 51-60
Yan, B.; Huang, D.; Hong, J.; Zhang, C. 2023: Design and fabrication of rotary magnetostrictvie energy harvester for knee-joint wearable applications Circuit World 49(1): 67-79
Narolia, T.; Bharti, M.S.; Pathak, A. 2025: Design and Analysis of Rotary Piezoelectric Energy Harvester for Adaptive Wind Speed Conditions Journal of Vibration Engineering and Technologies 13(5): 287
Ibrahim, P.; Nassar, O.; Arafa, M.; Anis, Y. 2017: On adjusting the rotary inertia of a cantilever-type energy harvester for wideband operation Procedia Engineering 199: 3422-3427
Liu, L.; He, L.; Liu, X.; Han, Y.; Sun, B.; Cheng, G. 2022: Design and experiment of a low frequency non-contact rotary piezoelectric energy harvester excited by magnetic coupling Energy 258: 124882
Huan, X.; You, Y.; Wang, D.; Li, S.; Zhu, L.; Liao, Y. 2022: Design and Experiment of Rotary Cutter Disc Type Flat Stubble Cutting Device for King Grass Harvester Nongye Jixie Xuebao/Transactions of the Chinese Society for Agricultural Machinery 53(5): 112-124
Mengying, X.I.E.; Kean, A.W.; Edwards, B.; Wei, G.A.O.; Hu, P. 2014: Orthogonal experimental design of polydimethylsiloxane curing for the design of low-frequency vibrational energy harvester J. Intell. Mater. Syst. Struct 25(18): 2228-2234
Pennisi, G.; Mann, B.; Naclerio, N.; Stephan, C.; Michon, G. 2018: Design and experimental study of a Nonlinear Energy Sink coupled to an electromagnetic energy harvester Journal of Sound and Vibration 437: 340-357
Li, N.; Yang, F.; Luo, T.; Qin, L. 2023: Design and Experimental Investigation of an Ultra-Low Frequency, Low-Intensity, and Multidirectional Piezoelectric Energy Harvester with Liquid as the Energy-Capture Medium Micromachines 14(2)
Farias, W.P.; Souto, C.R.; Castro, A.C. 2022: Design and experimental study of a rotational piezoelectric energy harvester Journal of Instrumentation 17(10): P10017
Yang, C.; Shi, W.; Chen, C.; Gao, Y.; Wang, H. 2022: Design and Experimental Investigation of a Novel Piezoelectric Energy Harvester in Pneumatic System Energy Technology 10(6): 2200096
Fan, K.Q.; Chao, F.B.; Zhang, J.G.; Wang, W.D.; Che, X.H. 2014: Design and experimental verification of a bi-directional nonlinear piezoelectric energy harvester Energy Conversion and Management 86: 561-567
HuZhiChao; ChenYouQing; WangHai'ou; ZhangHuiJuan; XieHuanXiong; TianLiJia 2008: Design and experimental research on vibrating type peanut harvester Transactions Of The Chinese Society Of Agricultural Engineering: 10, 114-117
Allamraju, K.V.; Srikanth, K. 2016: Design and Experimental Study of Novel Piezoelectric Vibration Energy Impact Mass Harvester Procedia Engineering 144: 560-567
Chen, G.; Duan, B.; Zhu, Y.; Ma, H.; Zhou, S. 2025: Design, simulation and experimental validation of a breathing-driven electromagnetic energy harvester Mechanical Systems and Signal Processing 233: 112781
Castagnetti, D.; Radi, E. 2018: A piezoelectric based energy harvester with dynamic magnification: modelling, design and experimental assessment Meccanica 53(11-12): 2725-2742
Allamraju, K.V.; Korla, S. 2015: Novel Design, Analytical and Experimental Studies of Spring Comprised Piezo Electric Energy Harvester Materials Today: Proceedings 2(4-5): 2155-2163
Saadatnia, Z.; Esmailzadeh, E.; Naguib, H.E. 2018: Design, simulation, and experimental characterization of a heaving triboelectric-electromagnetic wave energy harvester Nano Energy 50: 281-290