COMPUTATIONAL FLUID DYNAMICS STUDY OF DUSTY AIR FLOW OVER NACA 63415 AIRFOIL FOR WIND TURBINE APPLICATIONS

Authors

  • Iham F. Zidane School of Engineering and Applied Science, Aston University, Aston Triangle, Birmingham, B4 7ET, U.K
  • Khalid M. Saqr Mechanical Engineering Department, College of Engineering and Technology, Arab Academy of Science. Technology and Maritime Transport, 1029 Abu Kir, Alexandria – Egypt
  • Greg Swadener School of Engineering and Applied Science, Aston University, Aston Triangle, Birmingham, B4 7ET, U.K
  • Xianghong Ma School of Engineering and Applied Science, Aston University, Aston Triangle, Birmingham, B4 7ET, U.K
  • Mohamed F. Shehadeh Marine Engineering Department, College of Engineering and Technology, Arab Academy of Science. Technology and Maritime Transport, 1029 Abu Kir, Alexandria – Egypt

DOI:

https://doi.org/10.11113/jt.v79.11877

Keywords:

Wind turbine, blade aerodynamics, multiphase flow, wind energy, sandy environment

Abstract

Gulf and South African countries have enormous potential for wind energy. However, the emergence of sand storms in this region postulates performance and reliability challenges on wind turbines. This study investigates the effects of debris flow on wind turbine blade performance. In this paper, two-dimensional incompressible Navier-Stokes equations and the transition SST turbulence model are used to analyze the aerodynamic performance of NACA 63415 airfoil under clean and sandy conditions. The numerical simulation of the airfoil under clean surface condition is performed at Reynolds number 460×103, and the numerical results have a good consistency with the experimental data. The Discrete Phase Model has been used to investigate the role sand particles play in the aerodynamic performance degradation. The pressure and lift coefficients of the airfoil have been computed under different sand particles flow rates. The performance of the airfoil under different angle of attacks has been studied. Results showed that the blade lift coefficient can deteriorate by 28% in conditions relevant to the Gulf and South African countries sand storms. As a result, the numerical simulation method has been verified to be economically available for accurate estimation of the sand particles effect on the wind turbine blades.

References

Mostafa Abdel-Geliel, I. F. Z., Mohammed Anany, Sohair F. Rezeka. 2014. Modeling and Simulation of a Hybrid Power Generation System of Wind Turbine, Micro-turbine and Solar Heater Cells. 11th IEEE International Conference on Control & Automation (ICCA). 2014: Taichung, Taiwan.

Zidane, I. F. et al. 2016. On the Role of Surface Roughness in the Aerodynamic Performance and Energy Conversion of Horizontal Wind Turbine Blades: A Review. International Journal of Energy Research. 40(15): 2054-2077.

Deshun, Li, R. L. 2010. Congxin Yang, Xiuyong Wang, Effects of Surface Roughness on Aerodynamic Performance of a Wind Turbine Airfoil. Power and Energy Engineering Conference (APPEEC).

Nianxin Ren, J. O. 2009. Numerical Dust Effect on the Performance of Wind Turbine Airfoils. Electromagnetic Analysis and Applications. 1: 102-107.

Hassan Salem, A. D., Zakaria Ghoneim. 2013. CFD Simulation and Analysis of Performance Degradation of Wind Turbine Blades in Dusty Environments. Power and Energy Engineering Conference (APPEEC). Madrid, Spain.

Mohammed, G. Khalfallah, A. M. K. 2007. Effect of Dust on the Performance of Wind Turbines. Desalination. 209: 209-220.

Esteban Ferrer, X. 2009. CFD Predictions of Transition and Distributed Roughness Over a Wind Turbine Airfoil. 47th AIAA Aerospace Sciences Meeting Including The New Horizons Forum and Aerospace Exposition. Orlando, Florida.

Launder, B. E. and D. Spalding. 1974. The Numerical Computation of Turbulent Flows. Computer Methods in Applied Mechanics and Engineering. 3(2): 269-289.

Yakhot, V., et al. 1992. Development of Turbulence Models for Shear Flows by a Double Expansion Technique. Physics of Fluids A. 4(7): 1510-1520.

Menter, F. R. 1993. Zonal Two Equation k-turbulence Models for Aerodynamic Flows. AIAA Paper. 2906.

DanÄová, P., et al. 2013. Comparison of Several Models of the Laminar/Turbulent Transition. EPJ Web of Conferences. 45: 01032.

ANSYS FLUENT Theory Guide. 2011.

Christian Bak, P. F., Jeppe Johansen, Ioannis and Antoniou. 2000. Wind Tunnel Tests of NACA 63-415 and a Modified NACA 63-415 Airfoil. Risø National Laboratory, Roskilde, Denmark, December

T. Mahdaoui, N. B., M. A. Madjoubi, C. Bousbaa. 2007. Study of the Effects of Sand Blasting on Soda Lime Glass Erosion. International Review of Mechanical Engineering. 1: 502-510.

Henley, P. 1990. Unpublished Soil Sample Report, Remote Sensing Division, Resewcl Institute, U.S. Army Engineer Topographic Laboratories, Ft Belvoir, VA. 21 Nov 90.

Downloads

Published

2017-11-20

Issue

Vol. 79 No. 7-3: Advances in Thermal Sciences and Fluid Flow

Section

Science and Engineering

License

Copyright of articles that appear in Jurnal Teknologi belongs exclusively to Penerbit Universiti Teknologi Malaysia (Penerbit UTM Press). This copyright covers the rights to reproduce the article, including reprints, electronic reproductions, or any other reproductions of similar nature.

How to Cite

COMPUTATIONAL FLUID DYNAMICS STUDY OF DUSTY AIR FLOW OVER NACA 63415 AIRFOIL FOR WIND TURBINE APPLICATIONS. (2017). Jurnal Teknologi, 79(7-3). https://doi.org/10.11113/jt.v79.11877