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Ultra-low-frequency and high-power Mag-Boost mechanism for ocean wave energy harvesting

Author

Listed:
  • Tang, Tianyi
  • Li, Yunfei
  • Huang, Manjuan
  • Mei, Mingqi
  • Wang, Zizhao
  • Zha, Fusheng
  • Sun, Lining
  • Liu, Huicong

Abstract

Ocean wave energy is a highly promising renewable energy source that plays a significant role in advancing sustainable development. However, the ultra-low-frequency and random characteristics of ocean waves pose significant challenges to efficient and high-power energy harvesting. This paper introduces an innovative Mag-Boost mechanism that ingeniously leverages sudden magnetic-torque variation in orthogonal magnetic fields to convert ultra-low excitation below 1 Hz into high-frequency oscillations exceeding 50 Hz in the power-magnet without direct contact. The energy conversion efficiency can be as high as 89.3 %. By integrating four Mag-Boost units into a circular array, this study presents a high-power wave energy harvester with ultra-low-frequency response capabilities. At a frequency of 1 Hz and an inclination angle of 25°, the harvester achieved a high output performance with a power of 1.79 W and a power density of 1.88 kW/m³, which is an order of magnitude higher than previously reported results. During offshore tests in the Yellow Sea, the wave energy harvester reached a peak open-circuit voltage of 10 V, providing a stable power supply for wireless temperature and humidity sensors. Furthermore, the Mag-Boost mechanism also demonstrates considerable potential for harvesting other forms of low-frequency environmental energy, including wind, vibration, and human kinetic energy.

Suggested Citation

  • Tang, Tianyi & Li, Yunfei & Huang, Manjuan & Mei, Mingqi & Wang, Zizhao & Zha, Fusheng & Sun, Lining & Liu, Huicong, 2025. "Ultra-low-frequency and high-power Mag-Boost mechanism for ocean wave energy harvesting," Renewable and Sustainable Energy Reviews, Elsevier, vol. 213(C).
    • Handle: RePEc:eee:rensus:v:213:y:2025:i:c:s1364032125001364
    DOI: 10.1016/j.rser.2025.115463
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