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2019 | nr 57 (129) | 11--20
Tytuł artykułu

Power and thrust coefficients of the horizontal axis tidal stream turbine with different twist angles, blade numbers, and section profiles

Treść / Zawartość
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The purpose of this research was to investigate the power and thrust coefficients of a horizontal axis tidal stream turbine (HATST) with different blade geometries, including twist angles, blade numbers, and section profiles. The RANS equations and Star-CCM+ commercial software were used to numerically analyze these variables. Furthermore, the turbulence model used in this study is a Realisable k-ε turbulent model. Nine different models were defined by changing the twist angle, thickness, camber, and blade numbers. The results are presented, and the power and thrust coefficients are compared against TSR for each of the nine different models. The pressure distribution and flow velocity contour are also presented and discussed.
Wydawca

Rocznik
Strony
11--20
Opis fizyczny
Bibliogr. 24 poz., rys., tab.
Twórcy
  • 1 Amirkabir University of Technology, Department of Maritime Engineering Tehran, Iran, gasemi@aut.ac.ir
  • Memorial University of Newfoundland, Department of Ocean and Naval Engineering St. John’s, Canada, david.molyneux@mun.ca
Bibliografia
  • 1. Abbasi, A., Ghassemi, H. & Molyneux, D. (2018) Numerical analysis of the hydrodynamic performance of HATST with different blade geometries. American Journal of Civil Engineering and Architecture 6(6), pp. 236–241.
  • 2. Bahaj, A.S., Molland, A.F., Chaplin, J.R. & Batten, W.M.J. (2007) Power and thrust measurements of marine current turbines under various hydrodynamic flow conditions in a cavitation tunnel and a towing tank. Renew. Energy 32 (3), pp. 407–426.
  • 3. Batten, W.M.J., Bahaj, A.S., Molland, A.F. & Chaplin, J.R. (2007) Experimentally validated numerical method for the hydrodynamic design of horizontal axis tidal turbines. Ocean Eng. 34(7), pp. 1013–1029.
  • 4. Batten, W.M.J., Bahaj, A.S., Molland, A.F. & Chaplin, J.R. (2008) The prediction of the hydrodynamic performance of marine current turbines. Renewable Energy 33, pp. 1085–1096.
  • 5. Dreyer, S.J., Polis, H.J. & Jenkins, L.D. (2017) Changing Tides: Acceptability, support, and perceptions of tidal energy in the United States. Energy Research & Social Science 29, pp. 72–83.
  • 6. Ebrahimi, S. & Ghassemi, M.A. (2018) Numerical aerodynamics analysis of the of the Archimedes screw wind turbine. Int. J Multidisciplinary Sci & Eng. (IJMSE) 9 (10), pp. 12–15.
  • 7. Ghassemi, H, Ghafari, H.R. & Homayoun, E. (2018) Hydrodynamic performance of the orizontal axis tidal stream turbine using RANS Solver. Scientific Journals of the Maritime University of Szczecin, Zeszyty Naukowe Akademia Morska w Szczecinie 55 (127), pp. 23–33.
  • 8. Gunawan, B.M.C. (2014) Model validation using experimental measurements from the Garfield thomas water tunnel at the applied research laboratory at Penn State University. In: Proceedings of the 2nd Marine Energy Technology Symposium.
  • 9. Hsiao, F.B., Bai, C.J. & Chong, W.T. (2013) The performance test of three different horizontal axis wind turbine (HAWT) blade shapes using experimental and numerical methods. Energies 6, pp. 2787–2803.
  • 10. Johnson, T., Jansujwicz, J. & Zydlewski, G. (2013) Tidal power development in Maine: stakeholder identification and perceptions of engagement. Estuaries Coasts 38(S1), pp. 266–278.
  • 11. Kerr, S., Watts, L., Colton. J., Conway, F., Hull, A., Johnson, K., Jude, S., Kannen, A., MacDougall, A., McLachlan, C., Potts, T. & Vergunst, J. (2014) Establishing an agenda for social studies research in marine renewable energy. Energy Policy 67, pp. 694–702.
  • 12. Nachtane, M., Tarfaoui, M., Saifaoui, D., El Moumen, A., Hassoon, O.H. & Benyahia, H. (2018) Evaluation of durability of composite materials applied to renewable marine energy: Case of ducted tidal turbine. Energy Reports 4, pp. 31–40.
  • 13. Nicolás-Pérez, F., Velasco, F.J.S., García-Cascales, J.R., Otón-Martínez, R.A., López-Belchi, A., Moratilla, D., Rey, F. & Laso, A. (2017) On the accuracy of RANS, DES and LES turbulence models for predicting drag reduction with Base Bleed technology. Aerospace Science and Technology 67, pp. 126–140.
  • 14. Noruzi, R., Vahidzadeh, M. & Riasi, A. (2015) Design, analysis and predicting hydrokinetic performance of a horizontal marine current axial turbine by consideration of turbine installation depth. Ocean Eng. 108, pp. 789–798.
  • 15. Rahimian, M., Walker, J. & Penesis, I. (2017) Numerical assessment of a horizontal axis marine current turbine performance. International Journal of Marine Energy 20, pp. 151–164.
  • 16. Ren, Y., Liu, B., Zhang, T. & Fang, Q. (2017) Design and hydrodynamic analysis of horizontal axis tidal stream turbines with winglets. Ocean. Eng. 144, pp. 374–383.
  • 17. Ruano-Chamorro, C., Castilla, J.C. & Gelcich, S. (2018) Human dimensions of marine hydrokinetic energies: current knowledge and research gaps. Renew Sustain Energy 82, pp. 1979–1989.
  • 18. Segura, E., Morales, R. & Somolinos, J.A. (2018) A strategic analysis of tidal current energy conversion systems in the European Union. Applied Energy 212, pp. 527–551.
  • 19. Seo, J., Lee, S-J., Choi, W-S., Park, S-T. & Hyung Rhee, S. (2016) Experimental study on kinetic energy conversion of horizontal axis tidal turbine. Renew. Energy 97, pp. 784– 797.
  • 20. Shi, W., Wang, D., Atlar, M. & Seo, K. (2013) Flow separation impacts on the hydrodynamic performance analysis of a marine current turbine using CFD. Proc. Inst. Mech. Eng. Part-A 227, pp. 833–846.
  • 21. Tampier, G., Troncoso, C. & Zilic, F. (2017) Numerical analysis of a diffuser-augmented hydrokinetic turbine. Ocean. Eng. 145, pp. 138–147.
  • 22. Xu, W. (2010) Numerical techniques for the design and prediction of performance of marine turbines and propellers. Master of Engineering Thesis in Department of Civil, Architectural and Environmental Eng., The University of Texas at Austin.
  • 23. Yan, J., Deng, X., Korobenko, A. & Bazilevs, Y. (2017) Free-surface flow modeling and simulation of horizontal-axis tidal-stream turbines. Computers and Fluids 158, Nov. 2017, pp. 157–166.
  • 24. Zhang, L., Wang, S-q. & Sheng, Q-h. (2015) The effects of surge motion of the floating platform on hydrodynamics performance of horizontal-axis tidal current turbine. Renew Energy 74, pp. 796–802.
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW
przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikatory
Identyfikator YADDA
bwmeta1.element.baztech-136fe9f8-8bd6-4a6c-aab9-3d6d0a7164e4
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