OpenFOAM for Francis Turbine Transients

OpenFOAM® Journal Pub Date : 2021-11-17 DOI:10.51560/ofj.v1.26

S. Salehi, H. Nilsson

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引用次数: 3

Abstract

The flexibility and fast responsiveness of hydropower systems make them a reliable solution to overcome the intermittency of renewable energy resources and balance the electrical grid. Therefore, investigating the complex flow fields during such operation is essential to increase the reliability and lifetime of future hydropower systems. The current article concerns the utilization of OpenFOAM for the numerical study of Francis turbines during transient load change operations. The details of employed models and numerical schemes are thoroughly explained. The Laplacian smoothing algorithm is applied for the deformation of the guide vane domain. The impact of different mesh diffusivity parameters on both load rejection and acceptance operations is studied. It is shown that general slip boundary conditions cannot be used for slipping points on the guide vane upper and lower surfaces. Instead, different alternatives are introduced and compared. The developed framework is tested on a high-head Francis turbine. Different transient operations are simulated and results are compared to the experimental data. It is shown that OpenFOAM can be employed as a trustworthy CFD solver for numerical investigation of Francis turbines transient operations.

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OpenFOAM弗朗西斯涡轮瞬变

水电系统的灵活性和快速响应性使其成为克服可再生能源间歇性和平衡电网的可靠解决方案。因此，研究这种运行过程中的复杂流场对提高未来水电系统的可靠性和使用寿命至关重要。本文关注的是利用OpenFOAM对混流式水轮机在瞬态负荷变化工况下的数值研究。详细说明了所采用的模型和数值格式。采用拉普拉斯平滑算法对导叶区域进行了变形处理。研究了不同网格扩散系数参数对甩负荷和接受负荷的影响。结果表明，一般滑移边界条件不能用于导叶上下表面的滑移点。相反，介绍并比较了不同的替代方案。所开发的框架在高水头混流式水轮机上进行了试验。模拟了不同的瞬态操作，并与实验数据进行了比较。结果表明，OpenFOAM可以作为混流式水轮机瞬态运行数值研究的可靠CFD求解器。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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OpenFOAM® Journal

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