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Broadband dual phase energy harvester: Vibration and magnetic field

Author

Listed:
  • Song, Hyun-Cheol
  • Kumar, Prashant
  • Sriramdas, Rammohan
  • Lee, Hyeon
  • Sharpes, Nathan
  • Kang, Min-Gyu
  • Maurya, Deepam
  • Sanghadasa, Mohan
  • Kang, Hyung-Won
  • Ryu, Jungho
  • Reynolds, William T.
  • Priya, Shashank

Abstract

Broadband mechanical energy harvesting implies stable output power over a wide range of source frequency. Here we present a cost-effective solution towards achieving broadband response by designing a magnetically coupled piezoelectric energy harvester array that exhibits a large power density of 243 μW/cm3 g2 at natural frequency and bandwidth of more than 30 Hz under 1 g acceleration. The magnetically coupled piezoelectric energy harvester array exhibits dual modes of energy harvesting, responding to both stray magnetic field as well as ambient vibrations, and is found to exhibit the output power density of 36.5 μW/cm3 Oe2 at 79.5 Hz under the ambient magnetic field while maintaining the broadband nature. The magnetically coupled piezoelectric energy harvester array was demonstrated to harvest continuous power from a rotary pump vibration, an automobile engine vibration and a parasitic magnetic field surrounding a cable of an electric kettle. These demonstrations suggest that the magnetically coupled piezoelectric energy harvester array could serve the role of a standalone power source for wireless sensor nodes and small electronic devices.

Suggested Citation

  • Song, Hyun-Cheol & Kumar, Prashant & Sriramdas, Rammohan & Lee, Hyeon & Sharpes, Nathan & Kang, Min-Gyu & Maurya, Deepam & Sanghadasa, Mohan & Kang, Hyung-Won & Ryu, Jungho & Reynolds, William T. & Pr, 2018. "Broadband dual phase energy harvester: Vibration and magnetic field," Applied Energy, Elsevier, vol. 225(C), pages 1132-1142.
    • Handle: RePEc:eee:appene:v:225:y:2018:i:c:p:1132-1142
    DOI: 10.1016/j.apenergy.2018.04.054
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    References listed on IDEAS

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    1. Wojtas, N. & Rüthemann, L. & Glatz, W. & Hierold, C., 2013. "Optimized thermal coupling of micro thermoelectric generators for improved output performance," Renewable Energy, Elsevier, vol. 60(C), pages 746-753.
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    Cited by:

    1. Wang, Chen & Lai, Siu-Kai & Wang, Jia-Mei & Feng, Jing-Jing & Ni, Yi-Qing, 2021. "An ultra-low-frequency, broadband and multi-stable tri-hybrid energy harvester for enabling the next-generation sustainable power," Applied Energy, Elsevier, vol. 291(C).
    2. Lee, Min-seon & Kim, Chang-il & Park, Woon-ik & Cho, Jeong-ho & Paik, Jong-hoo & Jeong, Young Hun, 2019. "Energy harvesting performance of unimorph piezoelectric cantilever generator using interdigitated electrode lead zirconate titanate laminate," Energy, Elsevier, vol. 179(C), pages 373-382.
    3. Sallam A. Kouritem & Muath A. Bani-Hani & Mohamed Beshir & Mohamed M. Y. B. Elshabasy & Wael A. Altabey, 2022. "Automatic Resonance Tuning Technique for an Ultra-Broadband Piezoelectric Energy Harvester," Energies, MDPI, vol. 15(19), pages 1-20, October.
    4. Chen, Lin & Liao, Xin & Sun, Beibei & Zhang, Ning & Wu, Jianwei, 2022. "A numerical-experimental dynamic analysis of high-efficiency and broadband bistable energy harvester with self-decreasing potential barrier effect," Applied Energy, Elsevier, vol. 317(C).
    5. Xie, Xiangdong & Zhang, Jiankun & Wang, Zijing & Li, Lingjie & Du, Guofeng, 2024. "The effect of magnetic proof masses on the energy harvesting bandwidth of piezoelectric coupled cantilever array," Applied Energy, Elsevier, vol. 353(PA).
    6. Paul, Kankana & Amann, Andreas & Roy, Saibal, 2021. "Tapered nonlinear vibration energy harvester for powering Internet of Things," Applied Energy, Elsevier, vol. 283(C).
    7. Liu, Weiqun & Yuan, Zhongxin & Zhang, Shuang & Zhu, Qiao, 2019. "Enhanced broadband generator of dual buckled beams with simultaneous translational and torsional coupling," Applied Energy, Elsevier, vol. 251(C), pages 1-1.
    8. Cong, Moyue & Gao, Yongzhuo & Wang, Weidong & He, Long & Mao, Xiwang & Long, Yi & Dong, Wei, 2024. "Asymmetry stagger array structure ultra-wideband vibration harvester integrating magnetically coupled nonlinear effects," Applied Energy, Elsevier, vol. 356(C).
    9. Gao, Xiangyu & Qiu, Chaorui & Li, Guo & Ma, Ming & Yang, Shuai & Xu, Zhuo & Li, Fei, 2020. "High output power density of a shear-mode piezoelectric energy harvester based on Pb(In1/2Nb1/2)O3-Pb(Mg1/3Nb2/3)O3-PbTiO3 single crystals," Applied Energy, Elsevier, vol. 271(C).
    10. Zhuang Lu & Quan Wen & Xianming He & Zhiyu Wen, 2019. "A Nonlinear Broadband Electromagnetic Vibration Energy Harvester Based on Double-Clamped Beam," Energies, MDPI, vol. 12(14), pages 1-12, July.
    11. Shim, Hyo-Kyung & Sun, Shuailing & Kim, Hyun-Soo & Lee, Dong-Gyu & Lee, Yeon-Jeong & Jang, Ji-Soo & Cho, Kyung-Hoon & Baik, Jeong Min & Kang, Chong-Yun & Leng, Yonggang & Hur, Sunghoon & Song, Hyun-Ch, 2022. "On a nonlinear broadband piezoelectric energy harvester with a coupled beam array," Applied Energy, Elsevier, vol. 328(C).
    12. Maurya, Deepam & Kumar, Prashant & Khaleghian, Seyedmeysam & Sriramdas, Rammohan & Kang, Min Gyu & Kishore, Ravi Anant & Kumar, Vireshwar & Song, Hyun-Cheol & Park, Jung-Min (Jerry) & Taheri, Saied & , 2018. "Energy harvesting and strain sensing in smart tire for next generation autonomous vehicles," Applied Energy, Elsevier, vol. 232(C), pages 312-322.
    13. Sun, Rujie & Li, Qinyu & Yao, Jianfei & Scarpa, Fabrizio & Rossiter, Jonathan, 2020. "Tunable, multi-modal, and multi-directional vibration energy harvester based on three-dimensional architected metastructures," Applied Energy, Elsevier, vol. 264(C).

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