Cavitation in torque converters may cause degradation in hydrodynamic performance, severe noise, or even blade damage. Researches have highlighted that the stator is most susceptible to the occurrence of cavitation due to the combination of high flow velocities and high incidence angles. The objective of this study is to therefore investigate the effects of cavitation on hydrodynamic performance as well as the influence of stator blade geometry on cavitation. A steady-state homogeneous computational fluid dynamics (CFD) model was developed and validated against test data. It was found that cavitation brought severe capacity constant degradation under low-speed ratio (SR) operating conditions and vanished in high-speed ratio operating conditions. A design of experiments (DOE) study was performed to investigate the influence of stator design variables on cavitation over various operating conditions, and it was found that stator blade geometry had a significant effect on cavitation behavior. The results show that stator blade count and leaning angle are important variables in terms of capacity constant loss, torque ratio (TR) variance, and duration of cavitation. Large leaning angles are recommended due to their ability to increase the cavitation number in torque converters over a wide range of SRs, leading to less stall capacity loss as well as a shorter duration of cavitation. A reduced stator blade count is also suggested due to a reduced TR loss and capacity loss at stall.
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April 2018
Research-Article
Influence of Stator Blade Geometry on Torque Converter Cavitation
Cheng Liu,
Cheng Liu
National Key Laboratory for Vehicular
Transmission,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: liuchengbit@gmail.com
Transmission,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: liuchengbit@gmail.com
Search for other works by this author on:
Wei Wei,
Wei Wei
National Key Laboratory for Vehicular
Transmission,
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: weiweibit@bit.edu.cn
Transmission,
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: weiweibit@bit.edu.cn
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Qingdong Yan,
Qingdong Yan
National Key Laboratory for Vehicular
Transmission,
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: yanqd@bit.edu.cn
Transmission,
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: yanqd@bit.edu.cn
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Brian K. Weaver,
Brian K. Weaver
Rotating Machinery and Controls Laboratory,
Mechanical and Aerospace Engineering
Department,
University of Virginia,
122 Engineer’s Way,
Charlottesville, VA 22904-4746
e-mail: bkw3q@virginia.edu
Mechanical and Aerospace Engineering
Department,
University of Virginia,
122 Engineer’s Way,
Charlottesville, VA 22904-4746
e-mail: bkw3q@virginia.edu
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Houston G. Wood
Houston G. Wood
Rotating Machinery and Controls Laboratory,
Mechanical and Aerospace Engineering
Department,
University of Virginia,
122 Engineer’s Way,
Charlottesville, VA 22904-4746
e-mail: hgw9p@virginia.edu
Mechanical and Aerospace Engineering
Department,
University of Virginia,
122 Engineer’s Way,
Charlottesville, VA 22904-4746
e-mail: hgw9p@virginia.edu
Search for other works by this author on:
Cheng Liu
National Key Laboratory for Vehicular
Transmission,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: liuchengbit@gmail.com
Transmission,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: liuchengbit@gmail.com
Wei Wei
National Key Laboratory for Vehicular
Transmission,
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: weiweibit@bit.edu.cn
Transmission,
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: weiweibit@bit.edu.cn
Qingdong Yan
National Key Laboratory for Vehicular
Transmission,
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: yanqd@bit.edu.cn
Transmission,
School of Mechanical Engineering,
Beijing Institute of Technology,
Beijing 100081, China
e-mail: yanqd@bit.edu.cn
Brian K. Weaver
Rotating Machinery and Controls Laboratory,
Mechanical and Aerospace Engineering
Department,
University of Virginia,
122 Engineer’s Way,
Charlottesville, VA 22904-4746
e-mail: bkw3q@virginia.edu
Mechanical and Aerospace Engineering
Department,
University of Virginia,
122 Engineer’s Way,
Charlottesville, VA 22904-4746
e-mail: bkw3q@virginia.edu
Houston G. Wood
Rotating Machinery and Controls Laboratory,
Mechanical and Aerospace Engineering
Department,
University of Virginia,
122 Engineer’s Way,
Charlottesville, VA 22904-4746
e-mail: hgw9p@virginia.edu
Mechanical and Aerospace Engineering
Department,
University of Virginia,
122 Engineer’s Way,
Charlottesville, VA 22904-4746
e-mail: hgw9p@virginia.edu
1The authors contributed equally to the paper.
2Corresponding author.
Contributed by the Fluids Engineering Division of ASME for publication in the JOURNAL OF FLUIDS ENGINEERING. Manuscript received April 10, 2017; final manuscript received September 15, 2017; published online November 23, 2017. Assoc. Editor: Devesh Ranjan.
J. Fluids Eng. Apr 2018, 140(4): 041102 (10 pages)
Published Online: November 23, 2017
Article history
Received:
April 10, 2017
Revised:
September 15, 2017
Citation
Liu, C., Wei, W., Yan, Q., Weaver, B. K., and Wood, H. G. (November 23, 2017). "Influence of Stator Blade Geometry on Torque Converter Cavitation." ASME. J. Fluids Eng. April 2018; 140(4): 041102. https://doi.org/10.1115/1.4038115
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