Numerical Model Parameters Choice of Helical Savonius Wind Rotor: CFD Investigation and Experimental Validation

Q2 Mathematics

CFD Letters Pub Date : 2024-06-02 DOI:10.37934/cfdl.16.10.94111

mariem lajnef, Mabrouk Mosbahi, abid Hasna, zied Driss, Emanuele Amato, Tullio Tucciarelli, Marco Sinagra

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Abstract

Electrical power is essential for human beings welfare. The available wind as a clean and renewable source of energy has whetted extensive interest over decades. Savonius vertical axis wind rotor as an energy converter has the merit of being adequate for specific implementations owing to its lower cost and independency on wind direction. From this perspective, multiple studies have been conducted to boost its efficiency. This research work emphasizes on the helical Savonius wind rotor (HSWR). The basic objective is to investigate the impact of selecting the numerical model parameters on its aerodynamic and performance characteristics. Experimental tests were realized with a 3D printed HSWR in a wind tunnel. The experimental performances in terms of power, static and dynamic torque coefficients were addressed. Next, a numerical study was undertaken through Ansys Fluent 17.0 software. Grid, turbulence model and rotating domain size tests were examined. Good accordance was obtained, which validated the numerical model with an averaged error of 5%. The maximum power coefficient proved to be equal to 0.124 at a tip speed ratio of 0.73 and 0.1224 at a tip speed ratio of 0.69, respectively, numerically and experimentally

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螺旋萨沃尼乌斯风力转子的数值模型参数选择：CFD 研究与实验验证

电力对人类福祉至关重要。几十年来，风能作为一种清洁的可再生能源引起了人们的广泛兴趣。萨沃尼乌斯垂直轴风力转子作为一种能源转换器，具有成本低、不受风向影响等优点，适合具体实施。从这个角度出发，已经开展了多项研究来提高其效率。这项研究工作的重点是螺旋萨沃尼风力转子（HSWR）。基本目标是研究数值模型参数的选择对其空气动力和性能特征的影响。在风洞中对 3D 打印的 HSWR 进行了实验测试。实验研究了功率、静态和动态扭矩系数方面的性能。接着，通过 Ansys Fluent 17.0 软件进行了数值研究。对网格、湍流模型和旋转域大小进行了测试。结果表明，数值模型的平均误差为 5%。数值和实验分别证明，在叶尖速度比为 0.73 时，最大功率系数等于 0.124；在叶尖速度比为 0.69 时，最大功率系数等于 0.1224。

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来源期刊

CFD Letters Chemical Engineering-Fluid Flow and Transfer Processes

CiteScore

3.40

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0.00%

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