高效重力水涡电厂变锥盆性能及流场数值研究

D. S. Pamuji, Nizam Effendi, D. Sugati
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引用次数: 4

摘要

现在,水电的利用仍然集中在大型水坝的开发上,这些水坝对自然环境有影响,经常受到该地区人民的反对。利用小的水资源发电,特别是利用引力涡旋的方法,目前已经引起了研究人员的兴趣。本文通过数值模拟研究了旋涡池的变化对重力水涡电厂性能和流场的影响。在ANSYS FLUENT程序中开发了基于流体体积法(VOF)的数值研究方法,用于分析GWVPP的参数研究。基于Nishi和Inagaki(2017)的研究,将进口直径和出口直径的比值(Din/Dout)改变3.26,将圆柱形涡池与重力型水轮机耦合,修改为锥形涡池型;4.9;和6.12。湍流模型采用RNG k-epsilon逼近,边界条件为入口质量流量为2.838 kg/s,开口和出口边界为0 Pa。因此,本研究的计算值与Nishi和Inagaki(2017)的扭矩和涡轮输出的实验数据一致。随后,对于随Din/Dout变化的锥形盆地,可以看出,最大流速剖面在接近出水孔处,从6.12开始依次为;4.9;其次是Din/Dout比的3.26。增大Din/Dout比或减小输出孔,增大空气面积,产生更大的涡流环流。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Numerical study on the performance and flow field of varied conical basin for efficient gravitational water vortex power plant
Nowadays, utilization of hydropower is still focussed on the development of large dams which have an effect on the natural environment and are often opposed by the people in the region. Producing electricity from small water resources, especially using the gravitational vortex method has currently attracted the interest of researchers. In this paper, a numerical study of the effect of vortex pool variation on the performance and flow field of gravitational water vortex power plant (GWVPP) are investigated. Numerical study based on the volume of fluid (VOF) method is developed in ANSYS FLUENT code program for analyzing the parametric studies of GWVPP. Cylindrical vortex pool coupled with gravitation type water turbine based on Nishi and Inagaki (2017) research, are modified become conical vortex pool type by varying the ratio of inlet diameter and outlet diameter (Din/Dout) by 3.26; 4.9; and 6.12. Turbulent model is approached using RNG k-epsilon and boundary conditions are set 2.838 kg/s for inlet mass flow rate, 0 Pa for open and outlet boundary. As a beginning result, the computational values of this study and experimental data of the torque and turbine output from Nishi and Inagaki (2017) agreed with one another. Later, for conical basin with variation of Din/Dout, it can be shown that the maximum velocity profile achieved in nearly to the discharge hole, in order from 6.12; 4.9; followed by 3.26 of the Din/Dout ratio respectively. It is supported by the increase in the Din/Dout ratio or decrease output hole, the air area increase and creat greater vortex circulation.
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