Numerical Investigation of Contra Rotating Vertical-Axis Tidal-Current Turbine

Dendy Satrio , I Ketut Aria Pria Utama , Mukhtasor

Journal of Marine Science and Application ›› 2018, Vol. 17 ›› Issue (2) : 208 -215.

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Journal of Marine Science and Application ›› 2018, Vol. 17 ›› Issue (2) : 208 -215. DOI: 10.1007/s11804-018-0017-5
Research Article

Numerical Investigation of Contra Rotating Vertical-Axis Tidal-Current Turbine

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Abstract

In this study, the performance of a contra rotating vertical-axis tidal-current turbine was investigated. The incompressible unsteady Reynolds-averaged Navier-Stokes (U-RANS) equations were solved via two-dimensional (2D) numerical simulation using ANSYS Fluent computational fluid dynamics (CFD) code. An algorithm known as SIMPLE from the CFD code was used to calculate the pressure-velocity coupling and second-order finite-volume discretization for all the transport equations. The base turbine model was validated using the available experimental data. Three given scenarios for the contra rotating turbine were modeled. The contra rotating turbine performs better in a low tip speed ratio (TSR) than in a high TSR operation. In a high TSR operation, the contra rotating turbine inefficiently operates, surviving to rotate in the chaotic flow distribution. Thus, it is recommended to use contra rotating turbine as a part of new design to increase the performance of a vertical-axis tidal-current turbine with a lower TSR.

Keywords

Tidal-current energy / Contra rotating turbine / Vertical-axis turbine / Two-dimensional computational fluid dynamics / Performance analysis

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Dendy Satrio, I Ketut Aria Pria Utama, Mukhtasor. Numerical Investigation of Contra Rotating Vertical-Axis Tidal-Current Turbine. Journal of Marine Science and Application, 2018, 17(2): 208-215 DOI:10.1007/s11804-018-0017-5

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References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Arini NR, Turnock SR, Tan M. A study of modified vertical axis tidal turbine to improve lift performance. Int J Electr Energy, 2016, 4(1): 37-41
[2]

Barbarelli S, Florio G, Amelio M, Scornaienchi NM, Cutrupi A, Zupone GL. Design procedure of an innovative turbine with rotors rotating in opposite directions for exploitation of the tidal currents. Energy, 2014, 77: 254-264 Elsevier
[3]

Bouzaher MT, Guerira B, Hadid M. Performance analysis of a vertical axis tidal turbine with flexible blades. J Marine Sci Appl, 2017, 16: 73-80

[4]

Cheng Z, Madsen HA, Gao Z, Moan T. Effects of the number of blades on the dynamics of floating straight-bladed vertical axis wind turbines. Renew Energy, 2017, 101: 1285-1298 Elsevier
[5]

Clarke JA, Connor G, Grant AD, Johnstone CM. Design and testing of a contra-rotating tidal current turbine. Proc IMechE A J Power Energy, 2007, 221: 171-179

[6]

Clarke J, Connor G, Grant A, Johnstone C, Ordonez-Sanchez S (2009) Contra-rotating marine current turbine: single point tethered floating system - stability and performance. In: Proceedings of the 8th European Wave and Tidal Energy Conference, Uppsala, Sweden
[7]

Gorban AN, Gorlov AM, Silantyev VM. Limits of the turbine efficiency for free fluid flow. J Energy Resour Technol ASME, 2001, 123: 311-317

[8]

Gorlov AM. Tidal energy, 2001, Boston: Academic Press, 2955-2960
[9]

Guang Z, Ran-sheng Y, Yan L, Peng-fei Z. Hydrodynamic performance of a vertical-axis tidal-current turbine with different preset angles of attack. J Hydrodyn, 2013, 25(2): 280-287 Elsevier
[10]

Güney MS, Kaygusuz K. Hydrokinetic energy conversion systems: a technology status review. Renew Sust Energy Rev, 2010, 14: 2996-3004 Elsevier
[11]

Huang B, Kanemoto T. Multi-objective numerical optimization of the front blade pitch angle distribution in a counter-rotating type horizontal-axis tidal turbine. Renew Energy, 2015, 81: 837-844 Elsevier
[12]

Kirke BK, Lazauskas L. Limitations of fixed pitch Darrieus hydrokinetic turbines and the challenge of variable pitch. Renew Energy, 2011, 36: 893-897 Elsevier
[13]

Le TQ, Lee K-S, Park J-S, Ko JH. Flow-driven rotor simulation of vertical axis tidal turbines: a comparison of helical and straight blades. Int J Nav Archit Ocean Eng, 2014, 6: 257-268 SNAK
[14]

Lee NJ, Kim IC, Kim CG, Hyun BS, Lee YH. Performance study on a counter-rotating tidal current turbine by CFD and model experimentation. Renew Energy, 2015, 79: 122-126 Elsevier
[15]

Luo XQ, Zhu GJ, Feng JJ (2014) Multi point design optimization of hydrofoil for marine current turbine. J Hydrodyn 26(5):807–817. https://doi.org/10.1016/S1001-6058(14)60089-5 Elsevier
[16]

Lynn PA. Electricity from wave and tide: an introduction to marine energy, 2014, London: Wiley, 1-5
[17]

Magagna D, Uihlein A. Ocean energy development in Europe: current status and future perspectives. Int J Mar Energy, 2015, 11: 84-104 Elsevier
[18]

Maitre T, Amet A, Pellon C. Modeling of the flow in a Darrieus water turbine: wall grid refinement analysis and comparison with experiments. Renew Energy, 2013, 51: 497-512 Elsevier
[19]

Marsh P, Ranmuthulaga D, Penesis I, Thomas G. Numerical investigation of the influence of blade helicity on the performance characteristics of vertical axis tidal turbines. Renew Energy, 2015, 81: 926-935 Elsevier
[20]

Marsh P, Ranmuthulaga D, Penesis I, Thomas G. Three-dimensional numerical simulations of straight-bladed vertical axis tidal turbines investigating power output, torque ripple and mounting force. Renew Energy, 2015, 83: 67-77 Elsevier
[21]

Marsh P, Ranmuthulaga D, Penesis I, Thomas G. The influence of turbulence model and two and three-dimensional domain selection on the simulated performance characteristics of vertical axis tidal turbines. Renew Energy, 2017, 105: 106-116 Elsevier
[22]

Mukhtasor (2014) Mengenal Energi Laut (in Bahasa). Surabaya, pp 1–13
[23]

Ordonez-Sanchez S, Grant A, Johnstone C (2010) Contra rotating marine turbines tank tests to analyse system dynamic response. 3rd International Conference on Ocean Energy, Bilbao, Spain, 1–6. DOI:https://www.icoe-conference.com/publication/contra_rotating_marine_turbines_tank_tests_to_analyse_system_dynamic_response/
[24]

Roh S-C, Kang S-H. Effects of a blade profile, the Reynolds number, and the solidity on the performance of a straight bladed vertical axis wind turbine. J Mech Sci Technol, 2013, 27(11): 3299-3307

[25]

Satrio D, Utama I K A P and Mukhtasor (2016) Vertical axis tidal turbine: advantages and challenges review. Proceeding of Ocean, Mechanical and Aerospace -Science and Engineering, Kuala Terengganu, Malaysia, 3:64–71. http://isomase.org/OMAse/Vol.3-2016/Section-1/3-7.pdf
[26]

Sheng Q, Khalid SS, Xiong Z, Sahib G, Zhang L. CFD simulation of fixed and variable pitch vertical axis tidal turbine with flexible blades. J Mar Sci Appl, 2013, 12: 185-192

[27]

Yuce MI, Muratoglu A. Hydrokinetic energy conversion systems: a technology status review. Renew Sust Energy Rev, 2015, 43: 72-82 Elsevier
[28]

Zanette J, Imbault D, Tourabi A. A design methodology for cross flow water turbines. Renew Energy, 2010, 35: 997-1009 Elsevier
[29]

Zeiner-Gundersen DH. A novel flexible foil vertical axis turbine for river, ocean, and tidal applications. Appl Energy, 2015, 151: 60-66 Elsevier
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