Numerical analyses of pressure fluctuations induced by interblade vortices in a model Francis turbine 被引量：12

Numerical analyses of pressure fluctuations induced by interblade vortices in a model Francis turbine

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摘要 Interblade vortices can greatly influence the stable operations of Francis turbines. As visible interblade vortices are essentially cavitating flows, i.e., the ones to cause interblade vortex cavitations, an unsteady simulation with a method using the RNG k- ？ turbulence model and the Zwart-Gerber-Belamri（ZGB） cavitation model is carried out to predict the pressure fluctuations induced. Modifications of the turbulence viscosity are made to improve the resolutions. The interblade vortices of two different appearances are observed from the numerical results, namely, the columnar and streamwise vortices, as is consistent with the experimental results. The pressure fluctuations of different frequencies are found to be induced by the interblade vortices on incipient and developed interblade vortex lines, respectively, on the Hill diagram of the model runner＇s parameters. From the centrifugal Rayleigh instability criterion, it follows that the columnar interblade vortices are stable and the streamwise interblade vortices are unstable in the model Francis turbine. Interblade vortices can greatly influence the stable operations of Francis turbines. As visible interblade vortices are essentially cavitating flows, i.e., the ones to cause interblade vortex cavitations, an unsteady simulation with a method using the RNG k- ？ turbulence model and the Zwart-Gerber-Belamri（ZGB） cavitation model is carried out to predict the pressure fluctuations induced. Modifications of the turbulence viscosity are made to improve the resolutions. The interblade vortices of two different appearances are observed from the numerical results, namely, the columnar and streamwise vortices, as is consistent with the experimental results. The pressure fluctuations of different frequencies are found to be induced by the interblade vortices on incipient and developed interblade vortex lines, respectively, on the Hill diagram of the model runner＇s parameters. From the centrifugal Rayleigh instability criterion, it follows that the columnar interblade vortices are stable and the streamwise interblade vortices are unstable in the model Francis turbine.

作者左志钢刘树红刘德民覃大清吴玉林

机构地区 Department of Thermal Engineering Research and Test Center State Key Laboratory of Hydro-power Equipment

出处《Journal of Hydrodynamics》 SCIE EI CSCD 2015年第4期513-521,共9页 水动力学研究与进展B辑（英文版）

基金 Project supported by the National Natural Science Foundation of China(Grant No.51476083) the National Science and Technology Ministry of China(Grant No.2011BAF03B01)

关键词 interblade vortices pressure fluctuations Francis turbine CAVITATION Rayleigh instability interblade vortices； pressure fluctuations； Francis turbine； cavitation； Rayleigh instability

分类号 TK733.1 [交通运输工程—轮机工程]

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