A new strategy for reducing pressure fluctuation of Francis turbine by bionic modification of local components

IF 7.1 2区 工程技术 Q1 ENERGY & FUELS
Jiafu Yang , Xiu Wang , Jun-Xian Pei, Yan Yan, Wen-Quan Wang
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Abstract

Long term operation of hydroelectric units in low load conditions can induce large-scale blade vortices, swirling vortex ropes in the draft tube, and low-frequency high amplitude pressure fluctuation. These phenomena will cause adverse consequences such as excessive vibration of the unit and blade breakage of the runner. Taking inspiration from the protuberances of the leading edge of a humped whale flipper, the present study firstly proposes bionic modifications of guide vanes and draft tube to suppress high-amplitude pressure fluctuations for Francis turbine. Numerical simulations of transient flow characteristics of the prototype unit (PU), the bionic guide vane unit (BG), and the bionic draft tube unit (BDG) under two low load conditions are conducted. Results indicated that the bionic draft tube has a good effect on suppressing pressure fluctuations in the vaneless area and draft tube. Under the Q/QBEF = 0.41 working condition, BDG causes the main frequency amplitude of pressure fluctuation at the center point of the draft tube inlet to change from 8000.2 Pa to 390.9 Pa, a decrease of 95.11 %. Under the Q/QBEF = 0.57 working condition, BDG causes the maximum decrease rate of the main frequency amplitude in the draft tube to be 60.5 %. The reducing effect in BDG of monitoring points in the guide vane area has reached over 43 %. Under low load conditions, the vortices near the wall in the draft tube of BDG are intercepted by bionic structures, reducing the vortex scale and helping to prevent the generation of large swirling vortex ropes. The bionic guide vanes have a significant control effect on pressure pulsation in the the guide vane and vaneless regions, although perform poorly in the draft tube.
通过仿生改造局部组件减少混流式涡轮机压力波动的新策略
水电机组在低负荷条件下长期运行会产生大规模叶片涡流、引水管中的漩涡绳和低频高幅压力波动。这些现象会导致机组过度振动和转轮叶片断裂等不良后果。本研究从驼峰鲸鳍前缘的突起中汲取灵感,首先提出对导叶和牵伸管进行仿生改造,以抑制混流式水轮机的高振幅压力波动。对原型机组(PU)、仿生导叶机组(BG)和仿生牵伸管机组(BDG)在两种低负荷条件下的瞬态流动特性进行了数值模拟。结果表明,仿生牵伸管对抑制无叶片区和牵伸管内的压力波动有很好的效果。在 Q/QBEF = 0.41 的工况下,BDG 使牵伸管入口中心点压力波动的主频幅值从 8000.2 Pa 变为 390.9 Pa,下降了 95.11 %。在 Q/QBEF = 0.57 的工况下,BDG 使牵伸管内主频振幅的最大下降率为 60.5 %。导叶区域监测点的 BDG 降低效果超过 43%。在低负荷条件下,BDG 牵伸管内靠近管壁的涡流被仿生结构拦截,从而减小了涡流尺度,有助于防止产生大的漩涡绳。仿生导向叶片对导向叶片和无叶片区域的压力脉动具有显著的控制效果,但在牵伸管中表现较差。
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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来源期刊
Sustainable Energy Technologies and Assessments
Sustainable Energy Technologies and Assessments Energy-Renewable Energy, Sustainability and the Environment
CiteScore
12.70
自引率
12.50%
发文量
1091
期刊介绍: Encouraging a transition to a sustainable energy future is imperative for our world. Technologies that enable this shift in various sectors like transportation, heating, and power systems are of utmost importance. Sustainable Energy Technologies and Assessments welcomes papers focusing on a range of aspects and levels of technological advancements in energy generation and utilization. The aim is to reduce the negative environmental impact associated with energy production and consumption, spanning from laboratory experiments to real-world applications in the commercial sector.
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