CFD-Modeling of the Airfoil of the Blades of a Wind Power Plant with a Vertical Axis in the Ansys Fluent System

Q3 Energy

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Pub Date : 2024-04-08 DOI:10.21122/1029-7448-2024-67-2-97-114

G. N. Uzakov, V. A. Sednin, A. Safarov, R. A. Mamedov, I. Khatamov

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Abstract

The article presents the results of research on modeling the DU-06-W-200 airfoil used in wind power plants with a vertical axis in the Ansys Fluent system, evaluating compatibility with experimental data and determining the optimal angle of attack. The DU-06-W-200 airfoil was simulated with angles of attack ranging from –15° to +15°, boundary conditions and input flow rate being of 15 m/s, operating temperature – of 23 °C, operating pressure – of 1·105 Pa, air flow rate – of 1.23 kg/m3 (airfoil chord length is of 1 m, dynamic viscosity of the air flow is 1.7894·10–5 kg/(m·s) and the type of turbulent models is SST k – omega (k – ω), k – epsilon (k – ε), whereas Reynolds number is 1.05·106). A two-dimensional geometry domain and a grid profile for the DU-06-W-200 airfoil have been created, with the number of nodes in the grid 37495 and the number of elements 36790. It was also found that the drag coefficients (Cd) SST k – omega (k – ω) for the turbulence model were equal to 0.1734, 0.0721, 0.0311, 0.0204, 0.0351, 0.0782, 0.1712, k – epsilon (k – ε) for the turbulence model were equal to 0.2065, 0.0789, 0.0318, 0.0212, 0.0359, 0.0787, 0.2019, lift coefficients (Cl) SST k – omega (k – ω) for the turbulence model were –0.9169, –0.9169, –0.9239, –0.5394, 0.0842, 0.7416, 1.3134, 1.1229, k – epsilon (k – ε) for the turbulent model was –0.9278, –0.8674, –0.5336, 0.0848, 0. 0359, 0.0787, 0.2019 at angles of attack of the DU-06-W-200 airfoil equal to –15°, –10o, –5°, 0°, 5°, 10°, 15°, respectively. In assessing the compatibility of the model and the experimental results of the DU-06-W-200 airfoil, the conformity criterion χ2, root mean square error (RMSE), coefficient of determination (R2), and average bias error (ABE) were used. Based on the results of a study of the dependence of the ratio of the drag and lift coefficients on changes in the angle of attack, carried out using the SST k – omega (k – ω) and k – epsilon (k – ε) turbulence models, it has been found that the maximum value of the ratio of the drag and lift coefficients is 21 at the optimal angle attack inclination equal to 5°.

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在 Ansys Fluent 系统中对垂直轴风力发电厂叶片机翼进行 CFD 建模

文章介绍了在 Ansys Fluent 系统中对垂直轴风力发电厂使用的 DU-06-W-200 机翼进行建模的研究成果，评估了与实验数据的兼容性，并确定了最佳攻角。模拟 DU-06-W-200 机翼时的攻角范围为 -15° 至 +15°，边界条件和输入流量为 15 m/s，工作温度为 23 °C，工作压力为 1-105 Pa，空气流量为 1.23 kg/m3（机翼弦长为 1 米，气流动态粘度为 1.7894-10-5 kg/(m-s)，湍流模型类型为 SST k - omega (k - ω)、k - epsilon (k - ε)，雷诺数为 1.05-106）。为 DU-06-W-200 机翼创建了二维几何域和网格剖面，网格节点数为 37495，元素数为 36790。还发现湍流模型的阻力系数（Cd）SST k - omega（k - ω）分别等于 0.1734、0.0721、0.0311、0.0204、0.0351、0.0782、0.1712, k - epsilon (k - ε) for the turbulence model were equal to 0.2065, 0.0789, 0.0318, 0.0212, 0.0359, 0.0787, 0.2019, lift coefficients (Cl) SST k - omega (k - ω) for the turbulence model were -0.9169, -0.9169, -0.9239, -0.5394, 0.0842, 0.7416, 1.3134, 1.1229, 湍流模型的 k - epsilon (k - ε) 分别为 -0.9278, -0.8674, -0.DU-06-W-200机翼的攻角分别为-15°、-10o、-5°、0°、5°、10°、15°时，湍流模型的k-ε分别为-0.9278、-0.8674、-0.5336、0.0848、0.0359、0.0787、0.2019。在评估模型与 DU-06-W-200 机翼实验结果的兼容性时，使用了符合性准则 χ2、均方根误差（RMSE）、判定系数（R2）和平均偏置误差（ABE）。根据使用 SST k - omega (k - ω) 和 k - epsilon (k - ε) 湍流模型对阻力系数和升力系数比值与攻角变化的关系进行研究的结果，发现在最佳攻角倾角等于 5°时，阻力系数和升力系数比值的最大值为 21。

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来源期刊

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Energy-Nuclear Energy and Engineering

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： The most important objectives of the journal are the generalization of scientific and practical achievements in the field of power engineering, increase scientific and practical skills as researchers and industry representatives. Scientific concept publications include the publication of a modern national and international research and achievements in areas such as general energetic, electricity, thermal energy, construction, environmental issues energy, energy economy, etc. The journal publishes the results of basic research and the advanced achievements of practices aimed at improving the efficiency of the functioning of the energy sector, reduction of losses in electricity and heat networks, improving the reliability of electrical protection systems, the stability of the energetic complex, literature reviews on a wide range of energy issues.