改进喷流控制对水轮机流动不稳定性的抑制

S. Deniz, Fabio Asaro
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引用次数: 1

摘要

在不断扩大的工况要求下,要使水泵水轮机稳定可靠地运行,往往对水泵水轮机的水力设计提出了挑战,需要有新的发展。在HSLU(瑞士卢塞恩应用科学大学)之前进行的一项研究中,通过采用不同的数值方法和应用几种湍流模型,开发了CFD方法,分析了低比速(即nq = 25)泵水轮机的流动不稳定性。目的是准确预测可逆泵水轮机在s形区域(转速空载工况下)的涡轮模式特性,并分析非设计工况下的流动特性。通过涡轮运行模式下不同导叶开度下的实验数据对该CFD模型进行了验证。基于对实验数据的分析、流动可视化和CFD结果,特别是对无叶空间和流道入口的流动特征进行了分析,探讨了流动不稳定的发生和发展。采用在模型水泵水轮机无叶空间注入空气和水的流动控制技术来抑制流量不稳定性,从而扩大水泵水轮机的工作范围。空气和水的注入都是通过外部能源(压缩机和泵)和分散的喷嘴进行的,这些喷嘴沿周向分布在无叶空间中。对水轮机运行模式下的s形泵-水轮机特性进行了修正,使转速空载条件下的斜率不再为正,表明稳定性行为得到改善。对非定常压力数据的分析表明,在无叶空间注入流体可以抑制旋转失速等流动不稳定性。流体注入对泵-水轮机特性的积极影响也在CFD计算中得到证实。计算流体力学(CFD)能够正确预测泵-水轮机无量纲流量、kcm2、转速、Ku1、注水特性曲线。在验证了CFD工具对注入流体的泵-涡轮特性的预测后,为了提高流动控制的有效性,并在可能的情况下,在无叶空间中使用更少的注入流体,进行了进一步的CFD模拟。目标是优化流体注入,以尽可能低的水/能量消耗来抑制不稳定性。喷射喷嘴的数量、喷嘴位置、喷嘴直径和喷射方向等参数都是不同的。利用CFD模拟分析了注水系统在周向和径向上改变喷嘴数量、位置和分布、无叶空间内相对于主流的流动喷射方向、无叶空间内喷嘴周向对称和不对称分布等几种配置方式。除了从轮毂壁面向无叶空间注入流动外,还研究了通过导叶的流体注入。将流体注入修改的结果与基线流量注入情况的结果进行了比较。通过参数研究,找到了最佳喷嘴配置,在涡轮工作模式下,与基线情况相比,喷嘴数量更少,注入流量更低,泵-涡轮性能稳定。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Improvements of Flow Control With Fluid Injection for the Suppression of Flow Instabilities in Pump-Turbines
A stable and reliable pump-turbine operation under continuously expanding operating range requirement often imposes challenges on the hydraulic design of the pump-turbines and requires new developments. During a previous study carried out at the HSLU (Lucerne University of Applied Sciences, Switzerland), the flow instabilities of a low specific speed (i.e., nq = 25) pump-turbine were analyzed while a CFD methodology was developed through taking different numerical approaches and applying several turbulence models. The goal was to predict the turbine-mode characteristics of the reversible pump-turbines in the S-shaped region (at speed no load conditions) accurately as well as analyzing the flow features especially at off-design conditions. This CFD model was validated against the experimental data at different guide vane openings in turbine operating mode. Based on the analysis of the experimental data, flow visualization, and CFD results focusing especially on the flow features in the vaneless space and at the runner inlet, the onset and development of the flow instabilities were explored. Furthermore, a flow control technology that entailed injecting air and water in the vaneless space of a model pump-turbine was implemented for suppressing the flow instabilities and thus extending the operating range of the pump-turbine. Both air- and water-injection were applied by using an external energy source (compressor and pump) and discrete nozzles that are distributed in the vaneless space circumferentially. The S-shaped pump-turbine characteristics in turbine operating mode were modified so that the slope at speed no load conditions was no more positive indicating an improvement in the stability behavior. The analysis of the unsteady pressure data indicates the suppression of flow instability such as rotating stall with fluid injection in the vaneless space. The positive effect of fluid injection on the pump-turbine characteristics was also demonstrated in the CFD calculations. CFD was able to predict the pump-turbine dimensionless discharge, Kcm1, - speed, Ku1, characteristic curve with water injection correctly. After the CFD tool is validated for the prediction of the pump-turbine characteristics with fluid injection, further CFD simulations were carried out in order to improve the effectiveness of flow control and if possible, using less amount of injected fluid in the vaneless space. The goal was to optimize the fluid injection so that the instabilities can be suppressed with the lowest possible water/energy consumption. Parameters such as number of injection nozzles, nozzle position, nozzle diameter, and injection direction are varied. Several configurations of water injection system i.e., changing the number, location, and distribution of injection nozzles circumferentially and radially, direction of flow injection with respect to the main flow in the vaneless space, symmetrical and asymmetrical circumferential distribution of the nozzles in the vaneless space were analyzed using the CFD simulations. In addition to the flow injection in the vaneless space from the hub wall, fluid injection through the guide vanes was also investigated. The results of the fluid injection modifications were compared with the results of the baseline flow injection case. Using a parameter study, optimal nozzle configurations were found, that resulted in stable pump-turbine behavior in turbine operating mode with fewer injection nozzles and lower injected flow rate in comparison to the baseline case.
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