Flow characteristics and influence associated with inter-blade cavitation vortices at deep part load operations of a Francis turbine

Abstract This paper focuses on the generation of twin vortex rope in the draft-tube elbow of a Francis turbine at deep part-load operation through analyzing the results of model tests along with numerical simulations. Model tests, including pressure fluctuations measurements, are conducted over 10 speed factors. By considering the frequency of the pressure fluctuations with respect to the swirl intensity at the runner outlet, the part-load operating range is divided into three regimes, with two clear transitions between each occurring at swirl numbers 0.4 and 1.7. For operating conditions with a swirl number S>0.4, a linear correlation between the frequency of the precessing vortex core and the swirl number is established. During deep part-load regime (S>1.7), low-frequency pressure fluctuations appear. Their frequency feature another linear correlation with the swirl number. Unsteady CFD simulation of the full domain is performed to elucidate the generation mechanisms of the low-frequency fluctuations. By tracking the center of the vortical structures along the draft-tube, generation of three vortices in the elbow responsible for the pressure fluctuations at the lowest frequency is highlighted: the main PVC hits the draft-tube wall in the elbow resulting in its break down into three vortices rotating with half the rotational speed of the PVC. Two of the vortices rotate with opposite angular position, constituting a structure of twin vortices. The periodic rotation of these three vortices in the elbow induces the low-frequency pressure fluctuations.

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Pressure measurements and high speed visualizations of the cavitation phenomena at deep part load condition in a Francis turbine

IOP Conference Series Earth and Environmental Science ◽

10.1088/1755-1315/22/2/022011 ◽

2014 ◽

Vol 22 (2) ◽

pp. 022011 ◽

Cited By ~ 9

Author(s):

K Yamamoto ◽

A Müller ◽

A Favrel ◽

C Landry ◽

F Avellan

Keyword(s):

High Speed ◽

Load Condition ◽

Francis Turbine ◽

Pressure Measurements ◽

Deep Part ◽

Part Load

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A Turbulence Model Assessment for Deep Part Load Conditions of a Francis Turbine

IOP Conference Series Earth and Environmental Science ◽

10.1088/1755-1315/774/1/012072 ◽

2021 ◽

Vol 774 (1) ◽

pp. 012072

Author(s):

J Wack ◽

J Beck ◽

P Conrad ◽

F von Locquenghien ◽

R Jester-Zürker ◽

...

Keyword(s):

Turbulence Model ◽

Francis Turbine ◽

Model Assessment ◽

Deep Part ◽

Part Load ◽

Load Conditions

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Physical Mechanism of Interblade Vortex Development at Deep Part Load Operation of a Francis Turbine

Journal of Fluids Engineering ◽

10.1115/1.4043989 ◽

2019 ◽

Vol 141 (11) ◽

Cited By ~ 5

Author(s):

Keita Yamamoto ◽

Andres Müller ◽

Arthur Favrel ◽

François Avellan

Keyword(s):

Energy Loss ◽

Physical Mechanism ◽

Vortex Structures ◽

Operating Conditions ◽

Francis Turbine ◽

Deep Part ◽

Seamless Integration ◽

Part Load ◽

Recirculating Flow ◽

Runner Blade

For seamless integration of growing electricity production from intermittent renewable energy sources, Francis turbines are under increasing demand to extend their operating range. This requires Francis turbines to operate under off-design conditions, where various types of cavitation are induced. At deep part load condition, an interblade cavitation vortex observed in a runner blade channel is a typical cavitation phenomenon causing pressure fluctuations and erosion, which prevent a reliable operation of Francis turbines at deep part load. The underlying mechanisms of its development are, however, yet to be understood. In an objective of revealing its developing mechanisms, the present study is aimed at investigating flow structures inside runner blade channels by comparison of three different operating conditions at deep part load using numerical simulation results. After demonstrating interblade vortex structures are successfully simulated by performed computations, it is shown that flow inside the runner at deep part load operation is characterized by a remarkable development of recirculating flow on the hub near the runner outlet. This recirculating flow is concluded to be closely associated with interblade vortex development. The skin-friction analyses applied to the hub identify the flow separation caused by a nonuniform distribution of flow, which describes the underlying physical mechanism of interblade vortex development. Investigations are further extended to include a quantitative evaluation of the specific energy loss induced by interblade vortex development. The integration of energy flux defined by rothalpy evidences the energy loss due to the presence of strong interblade vortex structures.

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Cavitation Effects on the Structural Resonance of Hydraulic Turbines: Failure Analysis in a Real Francis Turbine Runner

Energies ◽

10.3390/en11092320 ◽

2018 ◽

Vol 11 (9) ◽

pp. 2320 ◽

Cited By ~ 2

Author(s):

Xin Liu ◽

Yongyao Luo ◽

Alexandre Presas ◽

Zhengwei Wang ◽

Lingjiu Zhou

Keyword(s):

Natural Frequencies ◽

Local Maximum ◽

Hydraulic Turbine ◽

Francis Turbine ◽

Acoustic Medium ◽

Deep Part ◽

Multiple Fractures ◽

Part Load ◽

Turbine Runner ◽

Rotor Stator Interaction

When discussing potential resonances in hydraulic turbine runners, cavitation effects are usually neglected. Nevertheless, recent studies have experimentally proved, that large cavitation volumes in the proximity of flexible simple structures, such as hydrofoils, greatly modify their natural frequencies. In this paper, we analyze a resonance case in a Francis runner that leads to multiple fractures on the trailing edge of the blades, after just one day of operation at deep part load. If simple acoustic Fluid-Structure-Interaction (FSI) simulations are used, where the runner’s surrounding fluid is considered as a homogenous acoustic medium (water), the risk of structural resonances seems to be limited as the predicted natural frequencies are far enough from the excited frequencies by the flow. It is shown that the only hydraulic phenomenon which could have produced such fractures in the present case is the Rotor Stator Interaction (RSI). In order to analyze possible cavitation effects on the natural frequencies of the turbine runner, CFD simulations of the deep part load conditions have been performed, which predict large inter-blade vortex cavities. These cavities have been then introduced in the acoustical FSI model showing that under such conditions, natural frequencies of the runner increase approaching to some of the RSI excited frequencies. In particular, a possible resonance of the four-nodal diameter (4ND) mode has been found which would explain the fast behavior of the crack propagation. Furthermore, the shape and the position of the real fracture found agree with the local maximum stress spots at the junction between the trailing edges and the crown.

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Flow Field Investigation in Draft Tube of Francis Turbine at Off-Design Operation Using a Vortex Identification Algorithm

10.1115/fedsm2021-65742 ◽

2021 ◽

Author(s):

Sandeep Kumar ◽

Subodh Khullar ◽

Bhupendra K. Gandhi

Keyword(s):

Flow Field ◽

Vortex Breakdown ◽

Draft Tube ◽

Field Investigation ◽

Francis Turbine ◽

Identification Algorithm ◽

Deep Part ◽

Vortex Identification ◽

Stagnation Region ◽

Part Load

Abstract At off-design operations, flow instabilities such as vortex breakdown, reverse flows, and stagnant regions are observed in Francis turbines. The present work shows the numerical flow field investigations of a Francis turbine at two different part loads (PL) by employing a vortex identification algorithm. The analysis has been performed at various locations in the draft tube by extracting the velocity fields at different time steps of the simulation. The first operating point involves a fully developed rotating vortex rope (RVR) in the draft tube, which precesses at a frequency of 0.28 times of the runner rotation. The present algorithm is able to identify the regions along with the eccentric local rotation center. The second operating regime shows characteristics of deep part load with central solid body rotation in the draft tube flow field. The results show highly swirling flows with very low axial velocity. The flow is confined primarily near the walls. The analysis shows that the extent of stagnation region at deep part load is more and no inner shear layer is present as compared to the part-load operation. The spatial harmonic decomposition (SHD) of the pressure data is also performed to evaluate the synchronous and asynchronous components of pressure pulsations.

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