An improved deviation model for transonic stages in axial compressors

Xiaochen WANG; Xuesong LI; Xiaodong REN; Chunwei GU; Xiaobin QUE; Guoyu ZHOU

doi:10.1016/j.cja.2024.04.015

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Full Length Article | Open Access

An improved deviation model for transonic stages in axial compressors

Xiaochen WANG^{^a}, Xuesong LI^{^a^,}(

), Xiaodong REN^{^a}, Chunwei GU^{^a}, Xiaobin QUE^{^b}, Guoyu ZHOU^{^b}

Department of Energy and Power Engineering, Tsinghua University, Beijing 100084, China

China United Gas Turbine Technology Co. Ltd., Beijing 102209, China

Peer review under responsibility of Editorial Committee of CJA.

Show Author Information

Abstract

Deviation model is an important model for through-flow analysis in axial compressors. Theoretical analysis in classical deviation models is developed under the assumption of one-dimensional flow, which is controlled by the continuity equation. To consider three-dimensional characteristics in transonic flow, this study proposes an improved theoretical analysis method combining force analysis of the blade-to-blade flow with conventional analysis of the continuity equation. Influences of shock structures on transverse force, streamwise velocity and streamline curvature in the blade-to-blade flow are analyzed, and support the analytical modelling of density flow ratio between inlet and outlet conditions. Thus, a novel deviation model for transonic stages in axial compressors is proposed in this paper. The empirical coefficients are corrected based on the experimental data of a linear cascade, and the prediction accuracy is validated with the experimental data of a three-stage transonic compressor. The novel model provides accurate predictions for meridional flow fields at the design point and performance curves at design speed, and shows obvious improvements on classical models by Carter and Çetin.

Keywords

Transonic flow Axial compressor Aerodynamic performance Deviation model Through-flow method

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References

Wu CH. A general theory of three-dimensional flow in subsonic and supersonic turbomachines of axial, radial, and mixed-flow types. J Fluids Eng 1952;74(8):1363–80.

Crossref Google Scholar

Lieblein S. Incidence and deviation-angle correlations for compressor cascades. J Basic Eng 1960;82(3):575–84.

Crossref Google Scholar

Carter ADS. The low speed performance of related aerofoils in cascades. London: His Majesty’s Stationery Office; 1950. Report No.: CP-29.

Boyer KM, O’Brien WF. An improved streamline curvature approach for off-design analysis of transonic axial compression systems. J Turbomach 2003;125(3):475–81.

Crossref Google Scholar

Pollard D, Gostelow JP. Some experiments at low speed on compressor cascades. J Eng Power 1967;89(3):427–36.

Crossref Google Scholar

Creveling HF, Carmody RH. Axial flow compressor computer program for calculating off design performance (Program Ⅳ). Washington, D.C.: NASA; 1968. Report No.: CR-72427.

Roberts WB, Serovy GK, Sandercock DM. Modeling the 3-D flow effects on deviation angle for axial compressor middle stages. J Eng Gas Turbines Power 1986;108(1):131–7.

Crossref Google Scholar

Bode C, Kožulović D, Stark U, et al. Performance and boundary layer development of a high turning compressor cascade at suband supercritical flow conditions. Proceedings of ASME turbo expo 2012: Turbine technical conference and exposition. New York: ASME; 2013. p. 49–61.

Crossref

Swan WC. A practical method of predicting transonic-compressor performance. J Eng Power 1961;83(3):322–30.

Crossref Google Scholar

Fei T, Ji LC. Application of new empirical models based on mathematical statistics in the through-flow analysis. J Therm Sci 2021;30(6):2087–98.

Crossref Google Scholar

Zhang YY, Zhang SJ, Xiao YH. Aerodynamic performance prediction of transonic axial multistage compressors based on onedimensional meanline method. Proceedings of ASME turbo expo 2020: Turbomachinery technical conference and exposition. New York: ASME; 2021.

Crossref

Wu X, Liu B, Lei S, et al. Development of an improved streamline curvature approach for transonic axial compressor. Proceedings of ASME turbo expo 2016: Turbomachinery technical conference and exposition. 2016.

Çetin M, Üçer AŞ, Hirsch C, et al. An off-design loss and deviation prediction study for transonic axial compressors. Proceedings of ASME 1989 international gas turbine and aeroengine congress and exposition. New York: ASME; 1989.

Crossref

Hu JF, Zhu XC, Ouyang H, et al. Performance prediction of transonic axial compressor based on streamline curvature method. J Mech Sci Technol 2011;25(12):3037–45.

Crossref Google Scholar

Templalexis I, Pilidis P, Pachidis V, et al. Development of a 2-D compressor streamline curvature code. New York: ASME; 2006. Report No.: GT2006-90867.

Crossref

König WM, Hennecke DK, Fottner L. Improved blade profile loss and deviation angle models for advanced transonic compressor bladings: Part Ⅱ—A model for supersonic flow. J Turbomach 1996;118(1):81–7.

Crossref Google Scholar

Jansen W, Moffatt WC. The off-design analysis of axial-flow compressors. J Eng Power 1967;89(4):453–62.

Crossref Google Scholar

Al-Daini AJ. Loss and deviation model for a compressor blade element. Int J Heat Fluid Flow 1986;7(1):69–78.

Crossref Google Scholar

Roland W, Millar DAJ. Through flow calculations based on matrix inversion: Loss prediction. 4th meeting of the propulsion and energy panel, 1976.

Li B, Gu CW, Li XT, et al. Development and application of a throughflow method for high-loaded axial flow compressors. Sci China Technol Sci 2016;59(1):93–108.

Crossref Google Scholar

Wang XC, Ren XD, Li XS, et al. The endwall effects of stators with and without simplified penny gaps in a high-loaded multistage compressor. Proceedings of the ASME turbo expo 2020: Turbomachinerytechnical conference and exposition. New York: ASME; 2020.

Crossref

Schwenk FC, Lewis GW, Hartmann MJ. A preliminary analysis of the magnitude of shock losses in transonic compressors. Washington, D.C.: NASA; 1957. Report No.: NASA RM-E57A30.

Kaldellis JK. Parametrical investigation of the interaction between turbulent wall shear layers and normal shock waves, including separation. J Fluids Eng 1993;115(1):48–55.

Crossref Google Scholar

Schreiber HA, Starken H. Experimental cascade analysis of a transonic compressor rotor blade section. J Eng Gas Turbines Power 1984;106(2):288–94.

Crossref Google Scholar

Farahani AS, Amiri HB, Khazaei H, et al. The effect of Reynolds number on transonic compressor blade rotor section. Proceedings of ASME 2012 gas turbine India conference. New York: ASME; 2012.

Crossref

Chinese Journal of Aeronautics

Volume 37 Issue 7,
July 2024

Pages 93-108

DOI: 10.1016/j.cja.2024.04.015

Cite this article:

WANG X, LI X, REN X, et al. An improved deviation model for transonic stages in axial compressors. Chinese Journal of Aeronautics, 2024, 37(7): 93-108. https://doi.org/10.1016/j.cja.2024.04.015

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Received: 18 July 2023

Revised: 14 August 2023

Accepted: 29 October 2023

Published: 16 April 2024

This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).