Characterization of Swirling Inflow Effects on Turbine Performance under Pulsating Flows

DING Zhanming; WANG Cuicui; ZHANG Junyue; LIU Ying; HOU Linlin; ZHUGE Weilin; ZHANG Yangjun

doi:10.1007/s11630-022-1671-0

Journal of Thermal Science >

2022 , Vol. 31 >Issue 5: 1734 - 1744

DOI: https://doi.org/10.1007/s11630-022-1671-0

Aerothermodynamics

Characterization of Swirling Inflow Effects on Turbine Performance under Pulsating Flows

DING Zhanming ,
WANG Cuicui ,
ZHANG Junyue ,
LIU Ying ,
HOU Linlin ,
ZHUGE Weilin ,
ZHANG Yangjun

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1. Science and Technology on Diesel Engine Turbocharging Laboratory, China North Engine Research Institute, Tianjin 300400, China
2. Kangyue Technology (Shandong) Co., Ltd, Shouguang, Shandong 262718, China
3. State Key Laboratory of Automotive Safety and Energy, Tsinghua University, Beijing 100084, China

Online published: 2023-12-01

Supported by

The authors would like to thank the foundation of Science and Technology on Diesel Engine Turbocharging Laboratory (No.6142212190101) and Young Elite Scientists Sponsorship Program by CAST (2021QNRC001) for the supports.

Copyright

Science Press, Institute of Engineering Thermophysics, CAS and Springer-Verlag GmbH Germany, part of Springer Nature 2022

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Abstract

The present study focuses on the influence of the swirling flows on flow behaviors and performance of a radial-flow turbocharger turbine under pulsating inflow condition. To characterize the effects of swirling flow, three sets of simulations of the turbine were carried out, which are an unsteady simulation under pulsating swirling inflow, an unsteady simulation under equivalent pulsating uniform inflow, and quasi-steady simulations under uniform inflow. Results proved that swirling flow has a considerable negative influence on turbine instantaneous performance and lead to 2.5% cycle-averaged efficiency reduction under pulsating flow condition. Swirling inflow would lead to significant losses in both the volute and the rotor, while the pulsating inflow leads to higher losses in the rotor and shows little influence on the losses in the volute. The instantaneous efficiency reduction of the turbine could be correlated with the time-varying inlet swirl strength. Under the influence of unsteady inlet swirls, the volute flow field is highly distorted and the free vortex relation is no longer valid. The swirling flow has strong interactions with the wake flow of the volute tongue, leading to additional losses. Relative flow angle at rotor inlet is remarkably reduced and its distribution is significantly distorted. Strong separation flows and passage vortices would appear in the rotor because of the swirling inflow, leading to inferior rotor performance.

Key words： swirling inflow; pulsating flow; CFD; turbocharger turbine; internal combustion engine

Cite this article

DING Zhanming , WANG Cuicui , ZHANG Junyue , LIU Ying , HOU Linlin , ZHUGE Weilin , ZHANG Yangjun . Characterization of Swirling Inflow Effects on Turbine Performance under Pulsating Flows[J]. Journal of Thermal Science, 2022 , 31(5) : 1734 -1744 . DOI: 10.1007/s11630-022-1671-0

References

[1] Aghaali H., Ångström H-E., A review of turbocompounding as a waste heat recovery system for internal combustion engines. Renewable and Sustainable Energy Reviews, 2015, 49: 813–824.
[2] Baines N., Turbocharger turbine pulse flow performance and modelling 25 years on. 9th IMechE International Confererce on Turbochargers and Turbocharging, London, England, 2010, 5: 19–20. DOI: 10.1243/17547164C0012010028.
[3] Wallace F., Blair G., The pulsating-flow performance of inward radial-flow turbines. ASME 1965 Gas Turbine Conference and Products Show, Washington, 1965, February 28-March 4. DOI: 65-GTP-21.
[4] Dale A., Watson N., Vaneless radial turbocharger turbine performance. IMechE turbocharging and turbochargers, 1986: 65–76.
[5] Rajoo S., Martinez-Botas R., Unsteady effect in a nozzled turbocharger turbine. Journal of Turbomachinery, 2010, 132: 031001.
[6] Rajoo S., Romagnoli A., Martinez-Botas R.F., Unsteady performance analysis of a twin-entry variable geometry turbocharger turbine. Energy, 2012, 38: 176–189.
[7] Marelli S., Capobianco M., Steady and pulsating flow efficiency of a waste-gated turbocharger radial flow turbine for automotive application. Energy, 2011, 36: 459–465.
[8] Padzillah M.H., Rajoo S., Martinez-Botas R.F., Influence of speed and frequency towards the automotive turbocharger turbine performance under pulsating flow conditions. Energy Conversion and Management, 2014, 80: 416–428.
[9] Cao T., Xu L., Yang M., Martinez-Botas R.F., Radial turbine rotor response to pulsating inlet flows. Journal of Turbomachinery, 2014, 136: 071003.
[10] Qi M., Lei X., Wang Z., Ma C., Investigation on the flow characteristics of a VNT turbine under pulsating flow conditions. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 2017, 233(2): 396–412.
[11] Cerdoun M., Ghenaiet A., Unsteady behaviour of a twin entry radial turbine under engine like inlet flow conditions. Applied Thermal Engineering, 2018, 130: 93–111.
[12] Xue Y., Yang M., Martinez-Botas R.F., Yang B., Deng K., Unsteady performance of a mixed-flow turbine with nozzled twin-entry volute confronted by pulsating incoming flow. Aerospace Science and Technology, 2019, 95: 1–13.
[13] Zhao R.C., Li W.H., Zhuge W.L., Zhang Y.J., Unsteady flow loss mechanism and aerodynamic improvement of two-stage turbine under pulsating conditions. Entropy, 2019, 21(10): 985.
[14] Liu Z., Copeland C., Optimization of a radial turbine for pulsating flows. Journal of Engineering for Gas Turbines and Power, 2020, 142: 051009.
[15] Hellstrom F., Fuchs L., Effects of inlet conditions on the turbine performance of a radial turbine. ASME Turbo Expo 2008: Power for Land, Sea, and Air, Berlin, 2008, 6: 9–13. DOI: GT2008-51088.
[16] Westin F., Burenius R., Measurement of interstage losses of a twostage turbocharger system in a turbocharger test rig. SAE Paper 2010-01-1221. DOI: 10.4271/2010-01-1221.
[17] Zhao R., Zhuge W., Zheng X., Zhang Y., Yin Y., Li Z., Design of counter-rotating turbine to improve the off-design performance of turbo-compounding systems. ASME Turbo Expo 2013: Turbine Technical Conference and Exposition: American Society of Mechanical Engineers, San Antonio, 2013, 7: 3–7. DOI: GT2013-94412.
[18] Liu Y., Zhuge W., Zheng X., Zhang Y., Zhang S., Zhang J., Study of mechanism of counter-rotating turbine increasing two-stage turbine system efficiency. International Journal of Fluid Machinery and Systems, 2013, 6: 160–169.
[19] Liu Y.B., Zhuge W.L., Zhang Y.J., Zhang S.Y., Numerical analysis of flow interaction of turbine system in two-stage turbocharger of internal combustion engine. IOP Conference Series: Materials Science and Engineering, 2016, 129: 012004. DOI: 10.1088/1757-899x/129/1/012004.
[20] Hellstrom F., Fuchs L., Numerical computation of the pulsatile flow in a turbocharger with realistic inflow conditions from an exhaust manifold. ASME Turbo Expo 2009: Power for Land, Sea, and Air: American Society of Mechanical Engineers, Orlando, 2009, 6: 8–12. DOI: GT2009-59619.
[21] Kalpakli A., Örlü R., Tillmark N., Alfredsson P.H., Experimental investigation on the effect of pulsations on exhaust manifold-related flows aiming at improved efficiency. 10th International Conference on Turbochargers and Turbocharging, London, 2012, 5: 15–16.
[22] Lim S.M., Dahlkild A., Mihaescu M., Influence of upstream exhaust manifold on pulsatile turbocharger turbine performance. Journal of Engineering for Gas Turbines and Power, 2019, 141: 061010.
[23] Ding Z., Zhuge W., Zhang Y., Assessment of turbine performance under swirling inflow conditions. Energy, 2019, 168: 492–504.
[24] Ding Z., Zhuge W., Zhang Y., Chen Y., Liu C., Investigation on unsteady and steady swirling inflow effect on turbocharger turbine performance. ASME Turbo Expo 2019: Turbomachinery Technical Conference and Exposition, 2019. DOI: 10.1115/GT2019-91155.
[25] Jeong J., Hussain F., On the identification of a vortex. Journal of Fluid Mechanics, 1995, 285: 69–94.
[26] Futral S.M., Wasserbauer C.A., Off-design performance prediction with experimental verification for a radial-inflow turbine. National Aeronautics and Space Administration, 1965, pp.1–29.

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