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Maximal electric power generation from varying ocean waves with LC-tuned reactive PTO force (2404.08360v1)

Published 12 Apr 2024 in eess.SY and cs.SY

Abstract: The reactive Power Take Off (PTO) force is the key to maximizing mechanical power absorption and electric power generation of Wave Energy Converters (WECs) from ocean waves with variable frequency, but its study is limited due to its difficulty in physical realization. This paper presents a simple yet effective $LC$-tuned WEC that generates a tunable reactive PTO force from tunable inductor $L$ and capacitor $C$ in the WEC. A complete closed loop system model of the WEC is derived first, then three quantitative rules are obtained from analyzing the model. These rules are used to tune the $LC$ network, and hence the reactive PTO force that drives the WEC, to resonate with the input wave force and generate maximal electric power over a range of wave frequencies. Mathematical analysis of the WEC and tuning rules reveals the analytical and quantitative descriptions of the WEC's mechanical power absorption, active and reactive electric power generation and power factor, optimal electric resistance load, and the generator and $LC$ capacity requirements. Simulation results show the effectiveness and advantages of the proposed WEC and verify the analysis results.

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References (33)
  1. Richard Manasseh. Fluid Waves. CRC Press, 2021.
  2. Energy-maximizing control of wave-energy converters: The development of control system technology to optimize their operation. IEEE control systems magazine, 34(5):30–55, 2014.
  3. Hydrodynamic control of wave energy devices. Cambridge University Press, 2016.
  4. Review of control strategies for wave energy conversion systems and their validation: the wave-to-wire approach. Renewable and Sustainable Energy Reviews, 81:366–379, 2018.
  5. A fully coupled wave-to-wire model of an array of wave energy converters. IEEE Transactions on Sustainable Energy, 7(1):118–128, 2015.
  6. Effect of non-ideal power take-off on the energy absorption of a reactively controlled one degree of freedom wave energy converter. Applied Ocean Research, 48:236–243, 2014.
  7. Internally-resonant broadband point wave energy absorber. Energy Conversion and Management, 247:114751, 2021.
  8. Wave flume testing of an oscillating-body wave energy converter with a tuned inerter. Applied Ocean Research, 98:102127, 2020.
  9. Latching control of a floating oscillating-water-column wave energy converter. Renewable Energy, 90:229–241, 2016.
  10. Assessment of the influence of the distance between two wave energy converters on energy production. IET renewable power generation, 4(6):592–601, 2010.
  11. Power maximising control of a heaving point absorber wave energy converter. IET Renewable Power Generation, 15(14):3296–3308, 2021.
  12. Latching control of wave energy converters using tunable electrical load. In International Conference on Offshore Mechanics and Arctic Engineering, volume 86908, page V008T09A073. American Society of Mechanical Engineers, 2023.
  13. A continuous control approach to point absorber wave energy conversion. In 2016 UKACC 11th International Conference on Control (CONTROL), pages 1–6. IEEE, 2016.
  14. Active phase control for maximum power point tracking of a linear wave generator. IEEE transactions on power electronics, 32(10):7651–7662, 2016.
  15. Effect of control strategies and power take-off efficiency on the power capture from sea waves. IEEE Transactions on Energy Conversion, 26(4):1088–1098, 2011.
  16. A maximum capture width tracking controller for ocean wave energy converters in irregular waves. Ocean Engineering, 121:516–529, 2016.
  17. Maximum power point tracking control for mechanical rectification wave energy converter. IET Renewable Power Generation, 15(14):3138–3150, 2021.
  18. A comparison of efficiency-aware model-predictive control approaches for wave energy devices. Journal of Ocean Engineering and Marine Energy, 8(1):17–29, 2022.
  19. Limiting reactive power flow peaks in wave energy systems. IFAC-PapersOnLine, 55(31):427–432, 2022.
  20. Ocean Wave Energy Systems: Hydrodynamics, Power Takeoff and Control Systems. Springer, 2022.
  21. A review of wave-to-wire models for wave energy converters. Energies, 9(7):506, 2016.
  22. Wave variability along the world’s continental shelves and coasts: Monitoring opportunities from satellite earth observation. Advances in Space Research, 69(9):3236–3244, 2022.
  23. Wave-to-grid (w2g) control of a wave energy converter. Energy Conversion and Management: X, 14:100190, 2022.
  24. K. Budal. Theory for absorption of wave power by a system of interacting bodies. J. Ship Res., 21(4):248–253, 1977.
  25. Ye Li and Yi-Hsiang Yu. A synthesis of numerical methods for modeling wave energy converter-point absorbers. Renewable and Sustainable Energy Reviews, 16(6):4352–4364, 2012.
  26. Antonio F de O Falcao. Wave energy utilization: A review of the technologies. Renewable and sustainable energy reviews, 14(3):899–918, 2010.
  27. WE Cummins et al. The impulse response function and ship motions. 1962.
  28. Apram Rahoor. Comparison of control strategies for wave energy converters, 2020.
  29. Yifan Song. Design and Fabrication of a Linear Generator for Hybrid Systems. North Carolina State University, 2019.
  30. Peter F Ryff. Electric machinery. Prentice Hall, 1994.
  31. Huibert Kwakernaak. Modern signals and systems. Prentice Hall, 1991.
  32. James William Nilsson. Electric circuits. Pearson Education, 2008.
  33. Direct drive wave energy array with offshore energy storage supplying off-grid residential load. IET Renewable Power Generation, 11(9):1081–1088, 2017.

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