The effect of runner cone design on pressure oscillation characteristics in a Francis hydraulic turbine

Three-dimensional unsteady turbulent flow through the entire flow passage of a model Francis hydraulic turbine is simulated using the transition shear-stress transport turbulence model and verified with experimental data. Pressure oscillations with the original runner cone, an extended runner cone,...

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Bibliographic Details
Published in:Proceedings of the Institution of Mechanical Engineers. Part A, Journal of power and energy Journal of power and energy, 2012-02, Vol.226 (1), p.137-150
Main Authors: Qian, Z D, Li, W, Huai, W X, Wu, Y L
Format: Article
Language:English
Subjects:
Cavitation
Computational fluid dynamics
Draft tubes
Fluid flow
Hydraulics
Pressure
Pressure oscillations
Rope
Shear stress
Simulation
Turbines
Turbulence
Turbulent flow
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Summary:Three-dimensional unsteady turbulent flow through the entire flow passage of a model Francis hydraulic turbine is simulated using the transition shear-stress transport turbulence model and verified with experimental data. Pressure oscillations with the original runner cone, an extended runner cone, an extended runner cone with grooves, and a round-top runner cone are analysed under five operating conditions. The computational results show that (1) runner cone design can change the distribution pattern of the vortex rope in the draft tube and narrow the zone of special pressure oscillation; (2) the dominant frequency of pressure oscillation in the draft tube at guide vane opening angle, α = 17°, is significantly decreased by runner cone design while the peak-to-peak amplitude increased; (3) varying guide vane opening alters the influence of runner cone design on pressure oscillation; (4) the modified runner cones are effective for low frequency pressure oscillations induced by the vortex rope in the draft tube but have little effect on blade frequency pressure oscillation induced by rotor–stator interaction; (5) the cavitation performance at α = 17° is decreased while that at α = 18°, 19°, and 20° is increased by runner cone design; and (6) the round-top runner cone is most effective in decreasing pressure oscillations and increasing turbine cavitation performance.
ISSN:0957-6509
2041-2967
DOI:10.1177/0957650911422865