Investigation of Pressure Fluctuation and Pulsating Hydraulic Axial Thrust in Francis Turbines

Under the circumstances of rapid expansion of diverse forms of volatile and intermittent renewable energy sources, hydropower stations have become increasingly indispensable for improving the quality of energy conversion processes. As a consequence, Francis turbines, one of the most popular options,...

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Bibliographic Details
Published inEnergies (Basel) Vol. 13; no. 7; p. 1734
Main Authors Zhou, Xing, Shi, Changzheng, Miyagawa, Kazuyoshi, Wu, Hegao, Yu, Jinhong, Ma, Zhu
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.04.2020
Subjects
Design
Draft tubes
Electricity
Electricity distribution
Energy conversion
Energy sources
Fluctuations
Francis turbine
hydraulic axial thrust
Hydraulic loading
Hydraulics
Hydroelectric plants
Hydroelectric power
Hydroelectric power stations
Investigations
Load
numerical simulation
partial load operation
Pressure
pressure fluctuation
Pulsation
Renewable energy sources
Researchers
Simulation
Thrust bearings
Turbines
Turbulence models
Vortices
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Summary:Under the circumstances of rapid expansion of diverse forms of volatile and intermittent renewable energy sources, hydropower stations have become increasingly indispensable for improving the quality of energy conversion processes. As a consequence, Francis turbines, one of the most popular options, need to operate under off-design conditions, particularly for partial load operation. In this paper, a prototype Francis turbine was used to investigate the pressure fluctuations and hydraulic axial thrust pulsation under four partial load conditions. The analyses of pressure fluctuations in the vaneless space, runner, and draft tube are discussed in detail. The observed precession frequency of the vortex rope is 0.24 times that of the runner rotational frequency, which is able to travel upstream (from the draft tube to the vaneless space). Frequencies of both 24.0 and 15.0 times that of the runner rotational frequency are detected in the recording points of the runner surface, while the main dominant frequency recorded in the vaneless zone is 15.0 times that of the runner rotational frequency. Apart from unsteady pressure fluctuations, the pulsating property of hydraulic axial thrust is discussed in depth. In conclusion, the pulsation of hydraulic axial thrust is derived from the pressure fluctuations of the runner surface and is more complicated than the pressure fluctuations.
ISSN:1996-1073
1996-1073
DOI:10.3390/en13071734