Numerical analysis of flow-induced vibration of vanes in a giant Francis turbine

IF 7.1 2区工程技术 Q1 ENERGY & FUELS

Sustainable Energy Technologies and Assessments Pub Date : 2025-01-01 DOI:10.1016/j.seta.2024.104164

Guanzhe Cui , Yicheng Cao , Yan Yan , Wenquan Wang

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引用次数: 0

Abstract

Francis turbines play a crucial role in converting hydropower into electricity, addressing concerns associated with traditional energy sources. Flow instabilities around stay and guide vanes contribute to turbine vibration and significantly reduce energy harvesting efficiency. This study utilizes a highly accurate spectral element method and fluid–structure interaction algorithm to investigate the physical mechanisms behind vortex-induced vibrational phenomena around the cascades of a high-head prototype Francis turbine. The results reveal that favorable pressure gradients occur on the suction side of the guide vanes and stretch incoming small-scale vortices into elongated vortical structures that cause high-amplitude low-frequency fluctuation (f ≤ 10 Hz). Conversely, adverse pressure gradients on the pressure side induce numerous stochastic flow separations and small-scale vortices, resulting in a wide range of low-amplitude high-frequency pulsations. Additionally, the guide vanes exhibit higher magnitudes and vibrational amplitudes of the force coefficients compared to the stay vanes. Due to the substantial pressure difference between the upstream and downstream of the guide vanes, the operating condition with the high head and small attack angle demonstrates the most robust vibrational characteristics. The likelihood of resonance occurring in both vane and vaneless space is reduced since the frequencies of force coefficients concentrate at f ≤ 40 Hz, which are lower than the cascade natural frequencies. However, vortex shedding at the trailing edge of the guide vanes with a wide range of deterministic and irregular frequencies contributes to the highest amplitude of pressure pulsation, reaching 0.17 with a frequency of 230 Hz, potentially inducing turbine resonance. The study provides an in-depth explanation of the hydrodynamic characteristics of the cascades and thoroughly explains the physical mechanisms behind vortex-induced vibration in Francis turbines.

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来源期刊

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.