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A curved panel energy harvester for aeroelastic vibration

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  • Shan, Xiaobiao
  • Tian, Haigang
  • Chen, Danpeng
  • Xie, Tao

Abstract

This paper presents a novel flutter-induced vibration energy harvester with a curved panel for harvesting energy. A finite element model of the fluid-structure-electric coupling field was established to explore the effects of the airflow velocities, the load resistances, the locating positions and dimensions of the piezoelectric patches polyvinylidene fluoride (PVDF) on both the dynamic response and the energy harvesting performance of this curved panel harvester. Considering the cancellation effect of the opposite polarity charges in the same side of the piezoelectric patch at the same time, the energy harvester of the segmented piezoelectric patches attached to the curved panel was further studied for obtaining the optimal output power. An experimental wind tunnel and prototypes of the curved panel energy harvester were designed and fabricated. The results show that simulation and experimental results are in good agreement, and harvesting performance with the segmented piezoelectric patches is better than that of the continuous ones. The average output power first increase until it attains the maximum value, and then decrease with the external load resistance. A sustained output power density of 0.032 mW/cm3 is harvested at the airflow velocity of 25 m/s and the external load resistance of 10 MΩ. The present work provides an effective theoretical and experimental basis for further studying energy harvesting and vibration control of airfoil aircrafts.

Suggested Citation

  • Shan, Xiaobiao & Tian, Haigang & Chen, Danpeng & Xie, Tao, 2019. "A curved panel energy harvester for aeroelastic vibration," Applied Energy, Elsevier, vol. 249(C), pages 58-66.
  • Handle: RePEc:eee:appene:v:249:y:2019:i:c:p:58-66
    DOI: 10.1016/j.apenergy.2019.04.153
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    References listed on IDEAS

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    4. Hu, Gang & Tse, K.T. & Wei, Minghai & Naseer, R. & Abdelkefi, A. & Kwok, K.C.S., 2018. "Experimental investigation on the efficiency of circular cylinder-based wind energy harvester with different rod-shaped attachments," Applied Energy, Elsevier, vol. 226(C), pages 682-689.
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    Cited by:

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    3. Su Xian Long & Shin Yee Khoo & Zhi Chao Ong & Ming Foong Soong & Yu-Hsi Huang, 2023. "Numerical and Experimental Investigation of a Compressive-Mode Hull Piezoelectric Energy Harvester under Impact Force," Sustainability, MDPI, vol. 15(22), pages 1-14, November.
    4. Xiaobiao Shan & Haigang Tian & Han Cao & Tao Xie, 2020. "Enhancing Performance of a Piezoelectric Energy Harvester System for Concurrent Flutter and Vortex-Induced Vibration," Energies, MDPI, vol. 13(12), pages 1-19, June.
    5. Tian, Haigang & Shan, Xiaobiao & Li, Xia & Wang, Junlei, 2023. "Enhanced airfoil-based flutter piezoelectric energy harvester via coupling magnetic force," Applied Energy, Elsevier, vol. 340(C).
    6. Zuo, Jianyong & Dong, Liwei & Yang, Fan & Guo, Ziheng & Wang, Tianpeng & Zuo, Lei, 2023. "Energy harvesting solutions for railway transportation: A comprehensive review," Renewable Energy, Elsevier, vol. 202(C), pages 56-87.
    7. Othman, Ahmed M., 2022. "Synergy of robust adaptive emulated- controller and enhanced mud layers optimization for microgrid dynamics improvement," Renewable and Sustainable Energy Reviews, Elsevier, vol. 166(C).
    8. Shan, Xiaobiao & Sui, Guangdong & Tian, Haigang & Min, Zhaowei & Feng, Ju & Xie, Tao, 2022. "Numerical analysis and experiments of an underwater magnetic nonlinear energy harvester based on vortex-induced vibration," Energy, Elsevier, vol. 241(C).

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