Research on Aerodynamic Performance of an Wind Turbine Airfoil  With Leading Edge Ice

Leading edge erosion is a considerable threat to wind turbine performance and blade maintenance, and it is very imperative to accurately predict the influence of various degrees of erosion on wind turbine performance. In the present study, an attempt to investigate the effects of leading edge erosion on the aerodynamics of wind turbine airfoil is undertaken by using computational fluid dynamics (CFD) method. A new pitting erosion model is proposed and semicircle cavities were used to represent the erosion pits in the simulation. Two-dimensional incompressible Reynolds-averaged Navier–Stokes equation and shear stress transport (SST) k–ω turbulence model are adopted to compute the aerodynamics of a S809 airfoil with leading edge pitting erosions, where the influences of pits depth, densities, distribution area, and locations are considered. The results indicate that pitting erosion has remarkably undesirable influences on the aerodynamic performance of the airfoil, and the critical pits depth, density, and distribution area degrade the airfoil aerodynamic performance mostly were obtained. In addition, the dominant parameters are determined by the correlation coefficient path analysis method, results showed that all parameters have non-negligible effects on the aerodynamics of S809 airfoil, and the Reynolds number is of the most important, followed by pits density, pits depth, and pits distribution area. Meanwhile, the direct and indirect effects of these factors are analyzed, and it is found that the indirect effects are very small and the parameters can be considered to be independent with each other.

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Numerical Simulation of Influence with Surface Contamination on Aerodynamic Performance of Dedicated Wind Turbine Airfoil

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.724-725.572 ◽

2013 ◽

Vol 724-725 ◽

pp. 572-575

Author(s):

Pan Wu ◽

Chun Li ◽

Zhi Min Li

Keyword(s):

Numerical Simulation ◽

Wind Turbine ◽

Leading Edge ◽

Aerodynamic Performance ◽

Surface Contamination ◽

Suction Surface ◽

Airfoil Surface ◽

Pressure Surface ◽

Sst Turbulence Model ◽

Wind Turbine Airfoil

A Numerical simulation on the influence of airfoil surface contamination on the aerodynamic performance of wind turbines was performed. It chose the dedicated wind turbine airfoil as the research object. The k-ω Shear Stress Transmission (SST) turbulence model was selected for CFD calculation. The roughness height which arranged evenly on the airfoil was changed from 0.03mm to 2.0mm to obtain the sensitive roughness. The airfoil was divided into 18 sections for analyzing the effect on the lift & the drag coefficient, due to various locations of sensitive roughness. By comparing the result computed by XFOIL and CFD calculation, it can be known this airfoils sensitive locations in suction surface and pressure surface. The sensitive locations in suction surface were 53% and 92% from the chord line towards the leading edge, while 44% and 88% in pressure surface. The sensitive roughness in sensitive locations delayed the location of the transition point.

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A parametric study of the effect of leading edge spherical tubercle amplitudes on the aerodynamic performance of a 2D wind turbine airfoil at low Reynolds numbers using computational fluid dynamics

Energy Reports ◽

10.1016/j.egyr.2021.06.093 ◽

2021 ◽

Vol 7 ◽

pp. 4184-4196

Author(s):

D. Benavides Zadorozhna ◽

O. Benavides ◽

J. Sierra Grajeda ◽

S. Figueroa Ramirez ◽

L. de la Cruz May

Keyword(s):

Fluid Dynamics ◽

Computational Fluid Dynamics ◽

Wind Turbine ◽

Parametric Study ◽

Leading Edge ◽

Reynolds Numbers ◽

Aerodynamic Performance ◽

Low Reynolds Numbers ◽

Wind Turbine Airfoil ◽

Low Reynolds

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Flow control on wind turbine airfoil affected by the surface roughness using leading-edge protuberance

Journal of Renewable and Sustainable Energy ◽

10.1063/1.5116414 ◽

2019 ◽

Vol 11 (6) ◽

pp. 063304 ◽

Cited By ~ 3

Author(s):

Yinan Zhang ◽

Mingming Zhang ◽

Chang Cai

Keyword(s):

Surface Roughness ◽

Flow Control ◽

Wind Turbine ◽

Leading Edge ◽

Wind Turbine Airfoil

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Influence of leading-edge tubercles on the aerodynamic performance of a horizontal-axis wind turbine: A numerical study

Energy ◽

10.1016/j.energy.2021.122186 ◽

2021 ◽

pp. 122186

Author(s):

Wenliang Ke ◽

Islam Hashem ◽

Wenwu Zhang ◽

Baoshan Zhu

Keyword(s):

Wind Turbine ◽

Numerical Study ◽

Leading Edge ◽

Aerodynamic Performance ◽

Horizontal Axis ◽

Horizontal Axis Wind Turbine

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Aerodynamic Performance of Wind Turbine Airfoil DU 91-W2-250 under Dynamic Stall

Applied Sciences ◽

10.3390/app8071111 ◽

2018 ◽

Vol 8 (7) ◽

pp. 1111 ◽

Cited By ~ 6

Author(s):

Shuang Li ◽

Lei Zhang ◽

Ke Yang ◽

Jin Xu ◽

Xue Li

Keyword(s):

Wind Turbine ◽

Aerodynamic Performance ◽

Dynamic Stall ◽

Wind Turbine Airfoil

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Parametric exploration on the airfoil design space by numerical design of experiment methodology and multiple regression model

Proceedings of the Institution of Mechanical Engineers Part A Journal of Power and Energy ◽

10.1177/0957650919850426 ◽

2019 ◽

Vol 234 (1) ◽

pp. 3-18 ◽

Cited By ~ 1

Author(s):

Xingxing Li ◽

Ke Yang

Keyword(s):

Regression Model ◽

Wind Turbine ◽

Multiple Regression ◽

Design Space ◽

Leading Edge ◽

Multiple Regression Model ◽

Highly Nonlinear ◽

Numerical Design ◽

Wind Turbine Airfoil ◽

The Cost

Robust airfoil design is crucial to efficient, stable, and safe operation for modern wind turbines. However, even for deterministic wind turbine airfoil design, the problem is complex regarding to aerodynamic, acoustic, and structural requirements of wind turbine blades. Therefore, this study aims to assess the design variable impact, identify significant variables, and obtain the correlation with the airfoil responses, to reduce the cost of the airfoil robust optimization. In this paper, the optimal hypercube design method was applied to an airfoil designed by the National Advisory Committee for Aeronautics, NACA 63-421, which is commonly employed in the outboard modern wind turbine blade, to perform the numerical design of experiments. Then, a parametric exploration on the characteristics of airfoil design space by the multiple regression model and statistical analysis method were conducted. It was identified that in regular design space, the variations of aerodynamic and structural parameters are dominated by the airfoil camber and radius of leading edge. Meanwhile, the chord-wise position of the maximum thickness also has strong impacts on the airfoil performance. In further, the overall design spaces are explored to be highly nonlinear in aerodynamic and acoustic responses because of the nonlinear effects of the airfoil chord-wise position of the maximum camber and radius of leading edge. Strong but undesirable correlations were demonstrated between the maximum lift-to-drag ratio and the total sound pressure level. These findings could serve as a valuable guidance for wind turbine airfoil robust design to screen the stochastic design variables, simplify the design space, and reduce the cost.

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Effect of Single-Row and Double-Row Passive Vortex Generators on the Deep Dynamic Stall of a Wind Turbine Airfoil

Energies ◽

10.3390/en13102535 ◽

2020 ◽

Vol 13 (10) ◽

pp. 2535

Author(s):

Chengyong Zhu ◽

Tongguang Wang ◽

Jie Chen ◽

Wei Zhong

Keyword(s):

Wind Turbine ◽

Flow Separation ◽

Aerodynamic Performance ◽

Vortex Generators ◽

Dynamic Stall ◽

Aerodynamic Forces ◽

Double Row ◽

Single Row ◽

Maximum Angle ◽

Wind Turbine Airfoil

Passive vortex generators (VGs) have been widely applied on wind turbines to boost the aerodynamic performance. Although VGs can delay the onset of static stall, the effect of VGs on dynamic stall is still incompletely understood. Therefore, this paper aims at investigating the deep dynamic stall of NREL S809 airfoil controlled by single-row and double-row VGs. The URANS method with VGs fully resolved is used to simulate the unsteady airfoil flow. Firstly, both single-row and double-row VGs effectively suppress the flow separation and reduce the fluctuations in aerodynamic forces when the airfoil pitches up. The maximum lift coefficient is therefore increased beyond 40%, and the onset of deep dynamic stall is also delayed. This suggests that deep dynamic-stall behaviors can be properly controlled by VGs. Secondly, there is a great difference in aerodynamic performance between single-row and double-row VGs when the airfoil pitches down. Single-row VGs severely reduce the aerodynamic pitch damping by 64%, thereby undermining the torsional aeroelastic stability of airfoil. Double-row VGs quickly restore the decreased aerodynamic efficiency near the maximum angle of attack, and also significantly accelerate the flow reattachment. The second-row VGs can help the near-wall flow to withstand the adverse pressure gradient and then suppress the trailing-edge flow separation, particularly during the downstroke process. Generally, double-row VGs are better than single-row VGs concerning controlling deep dynamic stall. This work also gives a performance assessment of VGs in controlling the highly unsteady aerodynamic forces of a wind turbine airfoil.

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