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The effects of roll motion of the floating platform on hydrodynamics performance of horizontal-axis tidal current turbine

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Under the condition of actual sea state, hydrodynamic characteristics of floating horizontal-axis turbine are related to wave characteristics and floating carrier motion responses. We recently published the hydrodynamic performance and axial damping coefficient of the horizontal-axis tidal current turbine influenced by surge motion in constant inflow using CFD simulation (Zhang et al. Renew Energy 74:796–802, 2015). Encouraged by this result, this paper uses sliding mesh to analyze the hydrodynamic characteristics in uniform stream when the turbine is forced to roll and studies influences of different roll frequency, roll amplitude, and tip speed ratio on turbine’s performance. Roll-damping coefficient and added mass coefficient can be derived by torque almanacs curve of rolling turbine by the least square method. Results show that the turbine axial load, roll moment, and energy utilization ratio will fluctuate in roll motion; the more roll frequency and roll amplitude, and the more load and moment wave amplitude of momentary value. The crest value occurs in the balance position of rolling, while the amplitude of oscillation depends on the angular speed of rolling and rotating speed of the turbine. The frequency and amplitude of the roll have little impact on damping coefficient, but rotational speed of the turbine has positive impact on this coefficient. Results of this study can provide data to study motion response of floating carrier for floating tidal current turbine system and check the structural design and control of the electric output.

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  1. Zhang L, Li X-Z, Geng J et al (2013) Tidal current energy update 2013. Adv New Renew Energy 1(1):53–68

    Google Scholar 

  2. Zhang L, Li Z-C, Zhang X-W et al (2011) The status of research and application of vertical axis tidal turbine. Appl Energy Technol 9:1–7

    Google Scholar 

  3. Sheng Q-H, Zhao D-Y, Zhang L (2014) A design and numerical simulation of horizontal tidal turbine. J Harbin Eng Univ 35(4):389–394

    Google Scholar 

  4. Batten W, Bahaj AS, Molland AF et al (2008) The prediction of the hydrodynamic performance of marine current turbines. Renew Energy 33(5):1085–1096

    Article  Google Scholar 

  5. Myers LE, Bahaj AS (2010) Experimental analysis of the flow field around horizontal axis tidal turbines by use of scale mesh disk rotor simulators. Ocean Eng 37:218–227

    Article  Google Scholar 

  6. Lee JH, Park S, Kim DH et al (2012) Computational methods for performance analysis of horizontal axis tidal stream turbines. Appl Energy 98:512–523

    Article  Google Scholar 

  7. Ma Y, Zhang L, Sheng Q-H et al (2012) The test study on hydrodynamic characteristics of floating tidal power generation devices. J Huazhong Univ Sci Technol (Nat Sci Edit) 10(40):123–127

    Google Scholar 

  8. Faudot Celine (2012) Ole Gunnar Dahlhaug. Prediction of wave loads on tidal turbine blades. Energy Procedia 20:116–133

    Article  Google Scholar 

  9. Barltrop N, Varyani KS, Grant A et al (2007) Investigation into wave current interactions in marine current turbines. Proc Inst Mech Eng Part A J Power Energy 42:221–233

    Google Scholar 

  10. Galloway PW, Myers LE, Bahaj AS (2010) Studies of scale turbine in close proximity to waves. In: 3rd international conference on ocean energy, pp 1–6

  11. Luznik L, Flack KA, Lust EE, Taylor K (2013) The effects of surface waves on the performance characteristics of a model tidal turbine. Renew Energy 58:108–114

    Article  Google Scholar 

  12. Gaurier B, Davies P, Deuff A et al (2013) Flume tank characterization of marine current turbine blade behaviour undercurrent and wave loading. Renew Energy 59:1–12

    Article  Google Scholar 

  13. Galloway PW, Myers LE, Bahaj AS (2014) Quantifying wave and yaw effects on a scale tidal stream turbine. Renew Energy 63:297–307

    Article  Google Scholar 

  14. Lust EE, Luznik L, Flack KA et al (2014) The influence of surface gravity waves on marine current turbine performance. Mar Energy 3(4):27–40

    Google Scholar 

  15. Zhang L, Wang S-Q, Sheng Q-H et al (2015) The effects of surge motion of the floating platform on hydrodynamics performance of horizontal-axis tidal current turbine. Renew Energy 74:796–802

    Article  Google Scholar 

  16. Zou L-Q (2010) The least squares principle and simple application. Sci Technol Inf 23:282–283

    Google Scholar 

  17. Wang S-Q, Xiao G, Zhang L et al (2014) Supporting column influence analysis of horizontal axis tidal current turbine. J Huazhong Univ Sci Technol (Nat Sci Edit) 42(4):81–85

    Google Scholar 

  18. Wang S-Q (2015) Study on hydrodynamic characteristics of horizontal axis tidal current turbine under complicated environment, vol Chapter 2. Harbin engineering university, Harbin

    Google Scholar 

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This research work was financially supported by the National Science Foundation of China (No. 51209060, No. 51409065, and No. 11572094). It is also supported by the Harbin Special Study Fund for technological innovation (No. 2014RFQXJ017 and No. 2015RQQXJ014) and by the National Science Foundation of Heilongjiang Province (E2016021).

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Correspondence to Ke Sun.

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Wang, Sq., Sun, K., Zhang, Jh. et al. The effects of roll motion of the floating platform on hydrodynamics performance of horizontal-axis tidal current turbine. J Mar Sci Technol 22, 259–269 (2017).

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