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An efficient hydrodynamic method for cross-flow turbines performance evaluation and comparison with the experiment

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  • Abed, Bouabdellah
  • Benzerdjeb, Abdelouahab
  • Benmansour, Abdeljellil
  • Achache, Habib
  • Ferhat, Rabia
  • Debz, Abderrahmene
  • Gorlov, Alaxender M.

Abstract

Renewable energies are getting ongoing growing interest and so are cross-flow turbines to harness water energy to produce electrical energy. Use of numerical methods to evaluate and predict this type of turbine performance can be of major help. This paper presents a Darrieus turbine numerical performance results. The present numerical method uses hydrodynamics theory applied to this turbine with three rotating blades, taking in consideration their relative angle of attack and hydrodynamic coefficients changes with the azimuthal angle. A comparison of these results with our experimental results is done for five water flow velocities (V = 0.43–0.73 m/s). The computer source code developed in this study allows determining this turbine torque, mechanical power and their coefficients.

Suggested Citation

  • Abed, Bouabdellah & Benzerdjeb, Abdelouahab & Benmansour, Abdeljellil & Achache, Habib & Ferhat, Rabia & Debz, Abderrahmene & Gorlov, Alaxender M., 2021. "An efficient hydrodynamic method for cross-flow turbines performance evaluation and comparison with the experiment," Renewable Energy, Elsevier, vol. 180(C), pages 993-1003.
    • Handle: RePEc:eee:renene:v:180:y:2021:i:c:p:993-1003
    DOI: 10.1016/j.renene.2021.09.004
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