Erosion Wear on the Runner Shroud of a Francis Turbine

In present work Computational fluid dynamics analysis based erosion wear prediction is performed for Francis turbine components, especially the runner. For the geometrical parameters, Francis turbine model with steady state condition and viscous flow turbulence SST model using ANSYS Fluent. The erosion effect on all the three component such as spiral casing, runner & draft tube has been studied for different concentration of sand particles from 1% - 6%. For each of those concentration the effect of variation in size has been studied for different sizes 10 ?m - 80 ?m. Further the effect of total erosion was also analyzed for different particle size. Erosion damage is found close to the upper and lower portions of the leading edge of the stay vane. some erosion spots at guide vane on the blade pressure side where suction side has minimum erosion. Maximum erosion damage observed on runner especially at the middle of the blade. The draft tube situated closer to runner having highest velocity due to high absolute velocity of water coming out from the runner does not produce any serious erosion effect. Results shows that erosion rate is maximum on runner at particle size 80 ?m for all sand concentration 1% to 6% and minimum at 30 ?m. Thus, 30 ?m is the optimum size of sand particles for the erosion.

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Erosion Wear on Runner of Francis Turbine in Jhimruk Hydroelectric Center

Journal of Fluids Engineering ◽

10.1115/1.4047230 ◽

2020 ◽

Vol 142 (9) ◽

Author(s):

Zhongdong Qian ◽

Zilong Zhao ◽

Zhiwei Guo ◽

Biraj Singh Thapa ◽

Bhola Thapa

Keyword(s):

Erosion Rate ◽

Erosive Wear ◽

Suction Side ◽

Francis Turbine ◽

Erosion Wear ◽

Operation Condition ◽

Guide Vanes ◽

Accretion Rates ◽

Physical Erosion ◽

Main Action

Abstract Erosion wear is a major problem for hydraulic turbines operating on rivers from the Himalaya Mountains. The runner is the most important energy conversion component but it suffers heavy damage due to direct contact with the sediment-laden water. In this research, the runner's physical erosion wear mechanism is revealed using numerical simulations and the results are compared with damaged runners from Francis turbines in the Jhimruk Hydroelectric Center (JHC). Simulations show that high erosive wear occurs near the blade outlet on the suction side, which is consistent with site observations. Because of the high relative velocity at the runner outlet, the high accretion rate appears to be directly responsible for the heavy erosion rate. The adjustment of the guide vanes is the main action available in real situation to change the operation condition of turbine and flow separation can easily occur under off-design conditions, causing interblade vortex production. The vortex guides particles to one location where they gather, producing high accretion rates and aggravating erosion wear. This implies that the interblade vortex is the main factor that induces severe erosive wear at the blade outlet. When the angle of the guide vanes is adjusted to provide the highest efficiency, the erosion rate can be greatly reduced.

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Erosion wear performance of a surface diffusion alloyed coating on pure magnesium

International Journal of Materials Research (formerly Zeitschrift fuer Metallkunde) ◽

10.3139/146.110841 ◽

2013 ◽

Vol 104 (2) ◽

pp. 179-182

Author(s):

Youping Ma ◽

Xiulan Li ◽

Lei Yang

Keyword(s):

Surface Diffusion ◽

Pure Magnesium ◽

Erosion Wear ◽

Wear Performance

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Capability of Advanced Ultrasonic Inspection Technologies for Hydraulic Turbine Runners

Applied Sciences ◽

10.3390/app11104681 ◽

2021 ◽

Vol 11 (10) ◽

pp. 4681

Author(s):

Mohammad Ebrahim Bajgholi ◽

Gilles Rousseau ◽

Martin Viens ◽

Denis Thibault

Keyword(s):

Ultrasonic Inspection ◽

High Stress ◽

Welding Process ◽

Hydraulic Turbine ◽

Francis Turbine ◽

Detection Rates ◽

Critical Range ◽

Area Of Interest ◽

Ambitious Program ◽

Pulse Echo

This paper presents the results of a project aimed at evaluating the performance of ultrasonic techniques for detecting flaws in Francis turbine runners. This work is the first phase of a more ambitious program aimed at improving the reliability of inspection of critical areas in turbine runners. Francis runners may be utilized to supply power during peak periods, which means that they experience additional load stress associated with start and stop sequences. Inspection during manufacturing is then of paramount importance to remove as much as feasible all flaw initiation sites before the heat treatment. This phase one objective is to collect initial data on a simplified mock-up and then to compare the experimental ultrasonic data with the results of simulations performed by CIVA, a computer simulation package. The area of interest is the region with the highest stress between the blade and the web. A welded T-joint coupon made of UNS S41500 was manufactured to represent this high-stress area. During the FCAW welding process, ceramic beads were embedded in the weld to create discontinuities whose size is in the critical range to initiate a crack. Inspection of the material was carried out by various nondestructive testing (NDT) methods namely conventional pulse-echo, phased array, total focusing method (TFM). With these results, detection rates were obtained in order to compare the effectiveness of each method.

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