甩负荷过程水泵水轮机流激振动数值模拟研究

doi:10.11660/slfdxb.20220714

摘要/Abstract

摘要： 抽水蓄能电站甩负荷过渡过程中机组振动剧烈，有导致转轮疲劳破坏风险。为探究转轮流激振动特性，对水泵水轮机在甩负荷中的典型工况（时刻）进行CFD-FEM数值模拟，分析了压力脉动、转轮动应力和振动模态。结果表明：转速是影响转轮压力脉动和动应力的最重要因素，最大转速工况最危险，转轮内压力脉动最剧烈，叶片动应力值和振幅均大于其他工况；压力脉动导致转轮动应力波动，两者频谱特征一致；转轮最大动应力出现在叶片进口与上冠“T型”连接处，过渡过程中最大值均超过材料许用应力；水力激励力频率与转轮固有频率相差较大，转轮在计算工况发生共振的可能性较小。

关键词: 水力机械, 水泵水轮机, 甩负荷, 流激振动, 流固耦合, 数值模拟

Abstract: Vibrations of pump-turbine units are often severe during load rejection, and the resulted intensive alternating stress may lead to a fatigue failure of the runner. To investigate the flow-induced vibrations of a pump-turbine runner, flow patterns, dynamic stress, and vibration modes are analyzed for typical working conditions based on CFD-FEM simulations. The results show the rotational speed is the key factor that has the greatest influence on the pressure pulsation and dynamic stress of the runner. Working at the highest speed is the most adverse condition, resulting in the worst pressure pulsation, along with a dynamic stress and its fluctuating amplitude that both are larger than those in other working conditions. The fluctuation of runner stress is induced by pressure pulsation, both featured with similar frequency spectra. The peak dynamic stress of the runner is located at its T-shaped joint between the blade leading edge and the hub. In our calculations, the frequencies of hydraulic excitation forces are far away from the natural frequency of the runner, and therefore the runner will not resonate in this case.

Key words: hydraulic machinery, pump-turbine, load rejection, flow-induced vibration, fluid-structure interaction, CFD-FEM

唐茂嘉, 泰荣, 程永光, 刘珂. 甩负荷过程水泵水轮机流激振动数值模拟研究[J]. 水力发电学报, 2022, 41(7): 140-148.

TANG Maojia, TAI Rong, CHENG Yongguang, LIU Ke. Analysis of flow-induced vibrations of pump-turbines during load rejection by CFD-FEM simulations[J]. Journal of Hydroelectric Engineering, 2022, 41(7): 140-148.

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甩负荷过程水泵水轮机流激振动数值模拟研究

Analysis of flow-induced vibrations of pump-turbines during load rejection by CFD-FEM simulations

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