Radial flow variable nozzle turbine (VNT) enables better matching between a turbocharger and engine and can improve the engine performance as well as decrease the engine emissions, especially when the engine works at low-end operation points. With increased nozzle loading, stronger shock wave and clearance leakage flow may be generated and consequently introduces strong rotor–stator interaction between turbine nozzle and rotor, which is a key concern of rotor high-cycle fatigue (HCF) failure. With the purpose of developing a low shock wave intensity turbine nozzle, the influence of grooved vane on the shock wave characteristics is investigated in the present paper. A Schlieren visualization experiment was first carried out on a linear turbine nozzle with smooth surface and the behavior of the shock wave was studied. Numerical simulations were also performed on the turbine nozzle. Guided by the visualization and numerical simulation, grooves were designed on the nozzle surface where the shock wave was originated and numerical simulations were performed to investigate the influence of grooves on the shock wave characteristics. Results indicate that for a smooth nozzle configuration, the intensity of the shock wave increases as the expansion ratios increase, while the onset position is shifted downstream to the nozzle trailing edge. For a nozzle configuration with grooved vane, the position of the shock wave onset is shifted upstream compared to the one with a smooth surface configuration, and the intensity of the shock wave and the static pressure (Ps) distortion at the nozzle vane exit plane are significantly depressed.
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December 2017
Research-Article
Investigation on the Shock Control Using Grooved Surface in a Linear Turbine Nozzle
Xinguo Lei,
Xinguo Lei
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
Beijing Institute of Technology,
Beijing 100081, China
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Mingxu Qi,
Mingxu Qi
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: qimx@bit.edu.cn
Beijing Institute of Technology,
Beijing 100081, China
e-mail: qimx@bit.edu.cn
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Harold Sun,
Harold Sun
Research and Innovation Center,
Ford Motor Company,
Dearborn, MI 48124
Ford Motor Company,
Dearborn, MI 48124
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Liangjun Hu
Liangjun Hu
Research and Innovation Center,
Ford Motor Company,
Dearborn, MI 48124
Ford Motor Company,
Dearborn, MI 48124
Search for other works by this author on:
Xinguo Lei
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
Beijing Institute of Technology,
Beijing 100081, China
Mingxu Qi
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: qimx@bit.edu.cn
Beijing Institute of Technology,
Beijing 100081, China
e-mail: qimx@bit.edu.cn
Harold Sun
Research and Innovation Center,
Ford Motor Company,
Dearborn, MI 48124
Ford Motor Company,
Dearborn, MI 48124
Liangjun Hu
Research and Innovation Center,
Ford Motor Company,
Dearborn, MI 48124
Ford Motor Company,
Dearborn, MI 48124
1Corresponding author.
Contributed by the International Gas Turbine Institute (IGTI) of ASME for publication in the JOURNAL OF TURBOMACHINERY. Manuscript received August 19, 2017; final manuscript received August 25, 2017; published online October 3, 2017. Editor: Kenneth Hall.
J. Turbomach. Dec 2017, 139(12): 121008 (12 pages)
Published Online: October 3, 2017
Article history
Received:
August 19, 2017
Revised:
August 25, 2017
Citation
Lei, X., Qi, M., Sun, H., and Hu, L. (October 3, 2017). "Investigation on the Shock Control Using Grooved Surface in a Linear Turbine Nozzle." ASME. J. Turbomach. December 2017; 139(12): 121008. https://doi.org/10.1115/1.4037860
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