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A review on performance enhancement techniques for ambient vibration energy harvesters

Author

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  • Yildirim, Tanju
  • Ghayesh, Mergen H.
  • Li, Weihua
  • Alici, Gursel

Abstract

Due to increased demands for energy and the current limitations of batteries, a future prospective technology are vibration energy harvesters that convert kinetic vibration energy into electrical energy. These energy harvesters have the potential to be used in powering small electronic devices such as measurement equipment in remote or hostile environments where batteries are not a viable option. Current limitations of vibration based energy harvesters is the total available power generated and the frequency at which they effectively collect ambient vibration sources for producing power; this paper aims to review the current techniques that are being employed to enhance the performance of these devices. These techniques have been categorised into amplification techniques, resonance tuning methods and introducing nonlinear oscillations. Before this technology can be used effectively in applications enhancing the performance of ambient vibration energy harvesters needs to be addressed.

Suggested Citation

  • Yildirim, Tanju & Ghayesh, Mergen H. & Li, Weihua & Alici, Gursel, 2017. "A review on performance enhancement techniques for ambient vibration energy harvesters," Renewable and Sustainable Energy Reviews, Elsevier, vol. 71(C), pages 435-449.
  • Handle: RePEc:eee:rensus:v:71:y:2017:i:c:p:435-449
    DOI: 10.1016/j.rser.2016.12.073
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    References listed on IDEAS

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    Cited by:

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    4. He, Lipeng & Liu, Lei & Zhou, Jianwen & Yu, Gang & Sun, Baoyu & Cheng, Guangming, 2022. "Design and analysis of a double-acting nonlinear wideband piezoelectric energy harvester under plucking and collision," Energy, Elsevier, vol. 239(PD).
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    6. Shan, Xiaobiao & Li, Hongliang & Yang, Yuancai & Feng, Ju & Wang, Yicong & Xie, Tao, 2019. "Enhancing the performance of an underwater piezoelectric energy harvester based on flow-induced vibration," Energy, Elsevier, vol. 172(C), pages 134-140.
    7. Zhou, Jianwen & He, Lipeng & Yu, Gang & Liu, Lei & Gu, Xiangfeng & Wang, Yuecheng & Cheng, Guangming, 2022. "Research on cam frequency-increasing hybrid piezoelectric electromagnetic energy harvester with center symmetric structure," Renewable Energy, Elsevier, vol. 185(C), pages 959-969.
    8. Nik Fakhri Nek Daud & Ruzlaini Ghoni, 2020. "Vibration Energy Harvesting Technique: A Comprehensive Review," Engineering Heritage Journal (GWK), Zibeline International Publishing, vol. 4(2), pages 46-48:4, October.
    9. Madinei, H. & Haddad Khodaparast, H. & Friswell, M.I. & Adhikari, S., 2018. "Minimising the effects of manufacturing uncertainties in MEMS Energy harvesters," Energy, Elsevier, vol. 149(C), pages 990-999.
    10. Bashar Hammad & Hichem Abdelmoula & Eihab Abdel-Rahman & Abdessattar Abdelkefi, 2019. "Nonlinear Analysis and Performance of Electret-Based Microcantilever Energy Harvesters," Energies, MDPI, vol. 12(22), pages 1-26, November.
    11. Areeba Naqvi & Ahsan Ali & Wael A. Altabey & Sallam A. Kouritem, 2022. "Energy Harvesting from Fluid Flow Using Piezoelectric Materials: A Review," Energies, MDPI, vol. 15(19), pages 1-35, October.
    12. Yan Liu & Shuting Mo & Siyao Shang & Hai Wang & Peng Wang & Keyuan Yang, 2020. "Quad-Trapezoidal-Leg Orthoplanar Spring with Piezoelectric Plate for Enhancing the Performances of Vibration Energy Harvester," Energies, MDPI, vol. 13(22), pages 1-11, November.
    13. Vidal, João V. & Carneiro, Pedro M.R. & Soares dos Santos, Marco P., 2024. "A complete physical 3D model from first principles of vibrational-powered electromagnetic generators," Applied Energy, Elsevier, vol. 357(C).
    14. Rashid Naseer & Huliang Dai & Abdessattar Abdelkefi & Lin Wang, 2019. "Comparative Study of Piezoelectric Vortex-Induced Vibration-Based Energy Harvesters with Multi-Stability Characteristics," Energies, MDPI, vol. 13(1), pages 1-24, December.
    15. Chaiyan Jettanasen & Panapong Songsukthawan & Atthapol Ngaopitakkul, 2020. "Development of Micro-Mobility Based on Piezoelectric Energy Harvesting for Smart City Applications," Sustainability, MDPI, vol. 12(7), pages 1-16, April.
    16. Carneiro, Pedro & Soares dos Santos, Marco P. & Rodrigues, André & Ferreira, Jorge A.F. & Simões, José A.O. & Marques, A. Torres & Kholkin, Andrei L., 2020. "Electromagnetic energy harvesting using magnetic levitation architectures: A review," Applied Energy, Elsevier, vol. 260(C).
    17. Zhu, Qiangguo & Wang, Guangqing & Zheng, Youcheng & Liu, Zhoulong & Zhou, Shuo & Zhang, Beiqi, 2022. "Coupling nonlinearities and dynamics between the hybrid tri-stable piezoelectric energy harvester and nonlinear interfaced circuit," Applied Energy, Elsevier, vol. 323(C).
    18. Tingting Zhang & Yanfei Jin, 2024. "Stochastic optimal control of a tri-stable energy harvester with the P-SSHI circuit under colored noise," The European Physical Journal B: Condensed Matter and Complex Systems, Springer;EDP Sciences, vol. 97(1), pages 1-13, January.
    19. Tian, Haigang & Shan, Xiaobiao & Sui, Guangdong & Xie, Tao, 2022. "Enhanced performance of piezoaeroelastic energy harvester with rod-shaped attachments," Energy, Elsevier, vol. 238(PB).

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