Performance Degradation due to Blade Surface Roughness in a Single-Stage Axial Turbine

Yun, Yong Il; Park, Il Young; Song, Seung Jin

doi:10.1115/1.1811097

Cited by 33 publications

(12 citation statements)

References 11 publications

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“…Yun et al [18] measured performance degradation in a single-stage axial turbine with roughened blades. The normalized efficiency decreased by 2% when the pressure side was roughened and by 6% when the suction side was roughened.…”

Section: Introductionmentioning

confidence: 99%

Effects of Reynolds Number and Surface Roughness Magnitude and Location on Compressor Cascade Performance

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Hobson

Song

et al. 2012

Journal of Turbomachinery

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An experimental investigation has been conducted to characterize the influence of Reynolds number and surface roughness magnitude and location on compressor cascade performance. Flow field surveys have been conducted in a low-speed, linear compressor cascade. Pressure, velocity, and loss have been measured via a five-hole probe, pitot probe, and pressure taps on the blades. Four different roughness magnitudes, Ra values of 0.38 μm (polished), 1.70 μm (baseline), 2.03 μm (rough 1), and 2.89 μm (rough 2), have been tested. Furthermore, various roughness locations have been examined. In addition to the as manufactured (baseline) and entirely rough blade cases, blades with roughness covering the leading edge, pressure side, and 5%, 20%, 35%, 50%, and 100% of suction side from the leading edge have been studied. All of the tests have been carried out for Reynolds numbers ranging from 300,000 to 640,000. For Reynolds numbers under 500,000, the tested roughnesses do not significantly degrade compressor blade loading or loss. However, loss and blade loading become sensitive to roughness at Reynolds numbers above 550,000. Cascade performance is more sensitive to roughness on the suction side than pressure side. Furthermore, roughness on the aft 2/3 of suction side surface has a greater influence on loss. For a given roughness location, there exists a Reynolds number at which loss begins to significantly increase. Finally, increasing the roughness area on the suction surface from the leading edge reduces the Reynolds number at which the loss begins to increase.

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Section: Introductionmentioning

confidence: 99%

Effects of Reynolds Number and Surface Roughness Magnitude and Location on Compressor Cascade Performance

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Hobson

Song

et al. 2012

Journal of Turbomachinery

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“…Yun et al [2] used sandpaper sheets with equivalent sand-grain roughness heights of 106 and 400 micrometers. The performance tests have been conducted in a low speed, single-stage, axial flow turbine having roughened blades.…”

Section: Experimental Workmentioning

confidence: 99%

Development of a Numerical Based Correlation for Performance Losses due to Surface Roughness in Axial Turbines

et al. 2014

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In the present work, a recently developed in-house 2D CFD code is used to study the effect of gas turbine stator blade roughness on various performance parameters of a two-dimensional blade cascade. The 2D CFD model is based on a high resolution flux difference splitting scheme of Roe (1981). The Reynolds Averaged Navier-Stokes (RANS) equations are closed using the zero-equation turbulence model of Baldwin-Lomax (1978) and two-equation Shear Stress Transport (SST) turbulence model. For the smooth blade, results are compared with experimental data to validate the model. Finally, a correlation between roughness Reynolds number and loss coefficient for both turbulence models is presented and tested for three other roughness heights. The results of 2D turbine blade cascades can be used for one-dimensional models such as mean line analysis or quasi-three-dimensional models e.g. streamline curvature method.

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“…Then, Yun et al [4] presented measurement and a mean-line analysis of turbine efficiency reduction due to blade surface roughness. Performance tests were conducted in a low-speed, single-stage, axial flow turbine with roughened blades.…”

Section: Introductionmentioning

confidence: 99%

Effects of surface roughness on deviation angle and performance losses in wet steam turbines

Esfe

Kermani

Saffar‐Avval

2015

Applied Thermal Engineering

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Performance Degradation due to Blade Surface Roughness in a Single-Stage Axial Turbine

Cited by 33 publications

References 11 publications

Effects of Reynolds Number and Surface Roughness Magnitude and Location on Compressor Cascade Performance

Effects of Reynolds Number and Surface Roughness Magnitude and Location on Compressor Cascade Performance

Development of a Numerical Based Correlation for Performance Losses due to Surface Roughness in Axial Turbines

Effects of surface roughness on deviation angle and performance losses in wet steam turbines

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