References
- 1. N.S. Diffenbaugh, D. Singh, and J.S. Mankin, Unprecedented climate events: Historical changes, aspirational targets, and national commitments, Sci. Advances, Vol. 4, eaao 3354, 2018.
- 2. H. Jeffrey, B. Jay, and M. Winskel, Accelerating the development of marine energy: Exploring the prospects, benefits and challenges, Technol. Forecast. Soc. Change, Vol. 80, pp. 1306–1316, 2013.
- 3. J. Van Zwieten, F.R. Driscoll, A. Leonessa, and G. Deane, “Design of a prototype ocean current turbine---Part I: mathematical modeling and dynamics simulation, Ocean Eng., Vol. 33, pp. 1485–1521, 2006.
- 4. F. Chen, The Kuroshio Power Plant, Switzerland: Springer, 2013.
- 5. IHI Corporation, Power generation using the Kuroshio Current, IHI Eng. Review, Vol. 46, pp. 2–5, 2014.
- 6. J.-Y. Bai, Ocean current power generation project, Workshop on Development of Marine Mechanical Energy Industry in Taiwan, Keelung, Taiwan, 2012 (in Chinese).
- 7. A. Røkke and R. Nilssen, Marine current turbines and generator preference: A technology review, Int. Conf. Renew. Energies Power Quality, Bilbao, Spain, 2013.
- 8. Y. Kyozuka, Tidal and ocean current power generation, J. Smart Processing, Vol. 3, pp. 137–145, 2014.
- 9. A.R. Cribbs, Model analysis of a mooring system for an ocean current turbine testing platform, M.S. thesis, Florida Atlantic University, Boca Raton, Florida, USA, Dec. 2010.
- 10. A.R. Cribbs and J.H. Van Zwieten, “Global numerical analysis of a moored ocean current turbine testing platform,” Oceans, Seattle, OR, USA, 2010.
- 11. M. Shibata, K. Takeda, and K. Takgai, Mooring and power cable system for current-turbine, Oceans, San Diego, CA, USA, 2013.
- 12. K. Takagi, T. Waseda, S. Nagaya, Y. Niizeki, and Y. Oda, Development of a floating current turbine, Oceans, Hampton Roads, VA, USA, 2012.
- 13. Y.-H. Rho, C.-H. Jo, and D.-Y. Kim, Optimization of mooring system for multi-arrayed tidal turbines in a strong current area, Proc. ASME 33rd Int. Conf. Ocean, Offshore and Arctic Eng., San Francisco, CA, USA, 2014.
- 14. C.C. Tsao and A.H. Feng, Motion Model and Speed Control of the Cross-Stream Active Mooring System for Tracking Short-Term Meandering to Maximize Ocean Current Power Generation, J. Mech., 1–15, 2017.
- 15. K. Shirasawa, J. Minami, and T. Shintake, Scale-model experiments for the surface wave influence on a submerged floating ocean-current turbine, Energies, Vol. 10, 702, 2017.
- 16. J.-T. Wu, J.-H. Chen, C.-Y. Hsin, and F.-C. Chiu, A computational study on system dynamics of an ocean current turbine, J. Hydrodyn., accepted, 2018.
- 17. A.R. Cribbs, G.R. Karrsten, J.T. Shelton, R.S. Nicoll, and W.P. Stewart, Mooring system considerations for renewable energy standards, Offshore Technology Conf., Houston, TX, USA, 2017.
- 18. A.E.D. Bowie, Flexible moorings for tidal current turbines, M.S. thesis, University of Strathclyde, Glasgow, UK, Sep. 2012.
- 19. C.H. Jo, D.Y. Kim, B.K. Cho, and M.J. Kim, Mooring analysis of duct-type tidal current power system in shallow water, Int. J. Geol. Environ. Eng., Vol. 10, pp. 577–582, 2016.
- 20. D.W. Atkins, The CFD assisted design and experimental testing of a wingsail with high lift devices, Ph.D. dissertation, University of Salford, Salford, UK, 1996.
- 21. H.Y. Lo, Dynamic analysis of current turbine system, M.S. thesis, National Taiwan Ocean University, Keelung, Taiwan, 2017 (in Chinese).
- 22. OrcaFlex Manual, Ver. 9.5a, Orcina Ltd., Cumbria, UK, 2011.
- 23. J.-T. Wu, J.-H. Chen, C.-Y. Hsin, and F.-C. Chiu, A computational study on system dynamics of an ocean current turbine, J. Hydrodyn., Vol. 30, pp. 395–402, 2018.