発電用ガスタービン実験機の翼への最適 リブレット効果予測と，そのレーザー加工 によるリブレット性能評価

Masayuki Shiraishi; Shintaro Tsuchihashi; Peter Adrian Leitl; Andreas Flanschger; Stefan  Schreck; Richard Benauer; Simon Pramstrahler; Andreas Marn

発電用ガスタービン実験機の翼への最適リブレット効果予測と，そのレーザー加工によるリブレット性能評価

Translated title of the contribution: Numerical and Experimental Investigation of Laser Processed Riblets on Turbine Exit Guide Vanes of Gas Turbine Test Rig and the Impact on the Performance

Masayuki Shiraishi, Shintaro Tsuchihashi, Peter Adrian Leitl, Andreas Flanschger, Stefan Schreck, Richard Benauer, Simon Pramstrahler, Andreas Marn

Research output: Contribution to journal › Article

Abstract

The reduction of pressure loss and wake in a low-pressure turbine test rig containing turbine exit guide vanes (TEGVs) with laser-processed riblet surface were numerically and experimentally investigated.
Riblets are streamwise grooved surfaces which reduce the viscous drag in a turbulent boundary layer, similar to shark-skin. An optimized riblet design was calculated by computational fluid dynamics (CFD), and the designed riblets were laser-processed directly onto the suction side of steel TEGVs. The TEGVs with and without riblets were installed on the test rig, and the effect of the riblets on the flow were
measured. Pressure loss around the TEGVs was reduced by 6.3 %. This result shows the benefit of laser-processed riblets directly fabricated on 3 -dimensionally curved parts, such as gas turbine blades, which operate at high temperatur

Translated title of the contribution	Numerical and Experimental Investigation of Laser Processed Riblets on Turbine Exit Guide Vanes of Gas Turbine Test Rig and the Impact on the Performance
Original language	Japanese
Pages (from-to)	33-40
Number of pages	8
Journal	Nikon Research Report
Volume	4
Publication status	Published - 2022

Keywords

Riblets
Laser Processing
CFD
Drag Reduction
Power Generation Efficienc

Access to Document

https://www.nikon.com/about/technology/rd/pdf/nrr_vol4_2022_06_e.pdfLicence: Unspecified

Cite this

Shiraishi, M., Tsuchihashi, S., Leitl, P. A., Flanschger, A., Schreck, S., Benauer, R., Pramstrahler, S., & Marn, A. (2022). 発電用ガスタービン実験機の翼への最適リブレット効果予測と，そのレーザー加工によるリブレット性能評価. Nikon Research Report, 4, 33-40. https://www.nikon.com/about/technology/rd/pdf/nrr_vol4_2022_06_e.pdf

Shiraishi, M, Tsuchihashi, S, Leitl, PA, Flanschger, A, Schreck, S, Benauer, R, Pramstrahler, S & Marn, A 2022, '発電用ガスタービン実験機の翼への最適リブレット効果予測と，そのレーザー加工によるリブレット性能評価', Nikon Research Report, vol. 4, pp. 33-40. <https://www.nikon.com/about/technology/rd/pdf/nrr_vol4_2022_06_e.pdf>

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abstract = "The reduction of pressure loss and wake in a low-pressure turbine test rig containing turbine exit guide vanes (TEGVs) with laser-processed riblet surface were numerically and experimentally investigated.Riblets are streamwise grooved surfaces which reduce the viscous drag in a turbulent boundary layer, similar to shark-skin. An optimized riblet design was calculated by computational fluid dynamics (CFD), and the designed riblets were laser-processed directly onto the suction side of steel TEGVs. The TEGVs with and without riblets were installed on the test rig, and the effect of the riblets on the flow weremeasured. Pressure loss around the TEGVs was reduced by 6.3 %. This result shows the benefit of laser-processed riblets directly fabricated on 3 -dimensionally curved parts, such as gas turbine blades, which operate at high temperatur",

keywords = "Riblets, Laser Processing, CFD, Drag Reduction, Power Generation Efficienc",

author = "Masayuki Shiraishi and Shintaro Tsuchihashi and Leitl, {Peter Adrian} and Andreas Flanschger and Stefan Schreck and Richard Benauer and Simon Pramstrahler and Andreas Marn",

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AU - Shiraishi, Masayuki

AU - Tsuchihashi, Shintaro

AU - Leitl, Peter Adrian

AU - Flanschger, Andreas

AU - Schreck, Stefan

AU - Benauer, Richard

AU - Pramstrahler, Simon

AU - Marn, Andreas

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KW - Riblets

KW - Laser Processing

KW - CFD

KW - Drag Reduction

KW - Power Generation Efficienc

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