International Journal of Advanced Engineering Application(IJAEA)
Published September 30, 2025 | Version v1
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Aerodynamic Optimization of Wind Turbine Blades Using Computational Fluid Dynamics

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The rapid evolution of multicore processor architectures has intensified the demand for efficient cache management Wind energy has emerged as a vital component of sustainable power generation, but maximizing its efficiency depends largely on the aerodynamic design of turbine blades. The present study focuses on the aerodynamic optimization of horizontal axis wind turbine blades using Computational Fluid Dynamics (CFD). Blade models were analyzed using ANSYS Fluent under varying wind speeds and angles of attack to evaluate lift, drag, and pressure distribution. Parametric optimization techniques were applied to modify chord length, twist angle, and airfoil geometry to enhance performance. Results indicate that optimized blade configurations achieved up to 14 percent improvement in power coefficient compared to baseline models, with a significant reduction in drag-to-lift ratio. Streamline and pressure contour analysis confirmed smoother flow separation and improved aerodynamic efficiency. The findings highlight that CFD-driven optimization is an effective approach for designing high-performance wind turbine blades, enabling greater energy capture and supporting the transition to renewable energy systems.

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https://www.ijaea.com/papers.php?paper=Aerodynamic+Optimization+of+Wind+Turbine+Blades+Using+Computational+Fluid+Dynamics

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2025-09-30
The rapid evolution of multicore processor architectures has intensified the demand for efficient cache management Wind energy has emerged as a vital component of sustainable power generation, but maximizing its efficiency depends largely on the aerodynamic design of turbine blades. The present study focuses on the aerodynamic optimization of horizontal axis wind turbine blades using Computational Fluid Dynamics (CFD). Blade models were analyzed using ANSYS Fluent under varying wind speeds and angles of attack to evaluate lift, drag, and pressure distribution. Parametric optimization techniques were applied to modify chord length, twist angle, and airfoil geometry to enhance performance. Results indicate that optimized blade configurations achieved up to 14 percent improvement in power coefficient compared to baseline models, with a significant reduction in drag-to-lift ratio. Streamline and pressure contour analysis confirmed smoother flow separation and improved aerodynamic efficiency. The findings highlight that CFD-driven optimization is an effective approach for designing high-performance wind turbine blades, enabling greater energy capture and supporting the transition to renewable energy systems.

References

  • [1] S. Sørensen, N. N. Sørensen, and P. Fuglsang, "Aerodynamic optimization of wind turbine blades using CFD," Wind Energy, vol. 5, no. 2, pp. 97–116, 2002. [2] M. O. Hansen, Aerodynamics of Wind Turbines, 3rd ed., Routledge, 2015. [3] L. Johansen, N. N. Sørensen, and C. Bak, "Design of high-efficiency wind turbine blades using CFD-based optimization," Journal of Physics: Conference Series, vol. 75, no. 1, pp. 012060, 2007. [4] T. Cebeci, "Analysis of airfoil aerodynamics for wind turbine blade design," Progress in Aerospace Sciences, vol. 39, no. 6–7, pp. 419–453, 2003. [5] A. Migliore and S. O. Ceylan, "Comparison of wind turbine airfoils using computational fluid dynamics," Journal of Solar Energy Engineering, vol. 127, no. 4, pp. 548–553, 2005. [6] S. Tangler and D. Somers, "NREL airfoil families for wind turbines," Wind Energy, vol. 8, no. 1, pp. 46–61, 2005. [7] Y. Yang, R. G. Rajagopalan, and R. W. Thresher, "Numerical simulation and optimization of wind turbine blades for offshore applications," Renewable Energy, vol. 86, pp. 143–152, 2016. [8] Z. Gao, X. Liu, and H. Li, "CFD analysis and aerodynamic optimization of horizontal axis wind turbine blades," Applied Energy, vol. 228, pp. 1629–1642, 2018. [9] M. Carrigan, A. Rumsey, and B. Cowan, "Aerodynamic shape optimization of wind turbine blades using adjoint CFD," Journal of Physics: Conference Series, vol. 555, pp. 012056, 2014. [10] S. Sarmast, C. Meneveau, and F. Porté-Agel, "Large eddy simulation of wind turbine wake interactions under optimized blade designs," Physics of Fluids, vol. 26, no. 10, pp. 105103, 2014. [11] J. Choudhury and A. Roy, "Performance analysis of wind turbine blades using NREL S-series airfoils," International Journal of Renewable Energy Research, vol. 7, no. 3, pp. 1210–1218, 2017. [12] H. Song, D. Lee, and Y. Park, "Multi-objective aerodynamic optimization of wind turbine blades considering aerodynamic and structural performance," Renewable Energy, vol. 134, pp. 989–1002, 2019. [13] P. Fuglsang and C. Bak, "Design and optimization of wind turbine rotor blades using a CFD-based genetic algorithm," Wind Engineering, vol. 28, no. 5, pp. 453–466, 2004. [14] L. Tongchitpakdee, L. Luo, and R. A. Agarwal, "Numerical study of three-dimensional effects on wind turbine blade aerodynamics," Journal of Solar Energy Engineering, vol. 127, no. 4, pp. 479–488, 2005. [15] N. L. Rezaeiha, A. Kalkman, and J. Blocken, "CFD simulation of vertical and horizontal axis wind turbines: Performance comparison and flow physics," Renewable Energy, vol. 131, pp. 210–226, 2019.