Performance of magneto-piezo-elastic cantilever circular array for low-speed efficient wind power generator application

Abstract

A magneto-piezo-elastic (MPE) cantilever generator using a PZT-based piezoelectric thick film with large dimensions of 120 and 60 mm was fabricated for wind power generator application, and a circular array of the MPE cantilevers was optimally designed by evaluating their output power performance. The geometric parameters of the gap (d) between coupled permanent magnets, and the distance (l) from the rotation axis, were found to influence the output voltage and start-up wind speed of the MPE cantilevers. The output power was strongly enhanced by accumulating the MPE cantilever circular arrays, depending on the decreased optimal resistive load and the increased optimal rotation per minute (rpm) of the Savonius wind blade. The highest output power of 333 mW at 500 Ω and 18 rpm was achieved by a triple circular array with 18 MPE cantilever generators. It was also demonstrated that the MPE cantilever circular array is sufficiently feasible in an actual windy environment, with superior output power in the low rpm ranges compared with commercial 300 W-rated wind turbines.

Keywords

magneto-piezo-elastic (MPE) energy conversion cantilever generator wind power PZT

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References

Akkaya Oy

Özdemir

(2018) Piezoelectric-based low-power wind generator design and testing. Arabian Journal for Science and Engineering 43(6): 2759–2767.

Akoun

Yonnet

(1984) 3D analytical calculation of the forces exerted between two cuboidal magnets. IEEE Transactions on Magnetics 20(5): 1962–1964.

Ali

Shaukat

, et al. (2024) Advancements in piezoelectric wind energy harvesting: A review. Results in Engineering 21: 101777.

Allag

Yonnet

(2009) 3-D analytical calculation of the torque and force exerted between two cuboidal magnets. IEEE Transactions on Magnetics 45(10): 3969–3972.

Çelik

Kurt

Uzun

(2017) Experimental and theoretical explorations on the buckling piezoelectric layer under magnetic excitation. Journal of Electronic Materials 46(7): 4003–4016.

Zhang

Chang

, et al. (2022) Micro windmill piezoelectric energy harvester based on vortex-induced vibration in tunnel. Energy 238: 121734.

Yeatman

(2017) A methodology for low-speed broadband rotational energy harvesting using piezoelectric transduction and frequency up-conversion. Energy 125: 152–161.

Lee

Park

, et al. (2024) Flutter-driven piezoelectric wind energy harvesting system based on PVDF nanofiber for low power applications. International Journal of Precision Engineering and Manufacturing-Green Technology 11(5): 1545–1556.

Han

Liu

, et al. (2022) Design and performance study of a rotating piezoelectric wind energy harvesting device with wind turbine structure. Energy 256: 124675.

10.

Jung

Song

Hong

, et al. (2015) Design and optimization of piezoelectric impact-based micro wind energy harvester for wireless sensor network. Sensors and Actuators A Physical 222: 314–321.

11.

Kim

Park

Key

, et al. (2023) Perovskite relaxor-dependent contributions to piezoelectric power generation of multiple PZT tape-based cantilever structures at nonresonant frequency. Advanced Energy Materials 13(37): 2301796.

12.

Zhou

Wang

, et al. (2024) A piezoelectric and electromagnetic hybrid energy harvester based on two-stage magnetic coupling. Mechanical Systems and Signal Processing 219: 111601.

13.

Jiang

, et al. (2022) Wind energy harvester using piezoelectric materials. Review of Scientific Instruments 93(3): 031502.

14.

McCarthy

Watkins

Deivasigamani

, et al. (2016) Fluttering energy harvesters in the wind: A review. Journal of Sound and Vibration 361: 355–377.

15.

Lee

M-S

Lee

, et al. (2020) Wind energy harvesting from a magnetically coupled piezoelectric bimorph cantilever array based on a dynamic magneto-piezo-elastic structure. Applied Energy 264: 114710.

16.

Lee

M-S

Lee

, et al. (2021) Horizontally assembled trapezoidal piezoelectric cantilevers driven by magnetic coupling for rotational energy harvester applications. Energies 14(2): 498.

17.

Pan

Zhang

, et al. (2021) Kinetic energy harvesting technologies for applications in land transportation: A comprehensive review. Applied Energy 286: 116518.

18.

Sun

Jang

Seok

(2021) Magnetically coupled piezoelectric galloping-based energy harvester using a tandem configuration. Mechanical Systems and Signal Processing 161: 107952.

19.

Wang

Yuan

, et al. (2023) Size effect of piezoelectric energy harvester for road with high efficiency electrical properties. Applied Energy 330: 120379.

20.

Wang

, et al. (2018) A bioinspired structure modification of piezoelectric wind energy harvester based on the prototype of leaf veins. Sensors and Actuators A Physical 279: 467–473.

21.

Yan

Shi

Zhou

, et al. (2021) Wind piezoelectric energy harvesting enhanced by elastic-interfered wake-induced vibration. Energy Conversion and Management 249: 114820.

22.

Zhang

Fang

, et al. (2020) Optimization of a piezoelectric wind energy harvester with a stepped beam. Journal of Mechanical Science and Technology 34(11): 4357–4366.

23.

Zhao

Yang

Lin

, et al. (2015) An arc-shaped piezoelectric generator for multi-directional wind energy harvesting. Sensors and Actuators A Physical 236: 173–179.

24.

Zhao

Zou

Wei

, et al. (2023) Mechanical intelligent energy harvesting: From methodology to applications. Advanced Energy Materials 13(29): 2300557.

25.

Zhao

L-C

Zou

H-X

Yan

, et al. (2019) A water-proof magnetically coupled piezoelectric-electromagnetic hybrid wind energy harvester. Applied Energy 239: 735–746.

26.

Zheng

Wang

, et al. (2023) A review of piezoelectric energy harvesters for harvesting wind energy. Sensors and Actuators A Physical 352: 114190.

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