Manufacturing Technology 2024, 24(6):992-1000 | DOI: 10.21062/mft.2024.100

Analysis of the Influencing Factors on the Oil Film Uniformity of Hydro-viscous Drive Clutch

Xiangping Liao ORCID..., Langxin Sun ORCID..., Shaopeng Kang ORCID..., Kailei Liu ORCID..., Xinyang Zhu ORCID..., Ying Zhao ORCID...
School of Mechanical Engineering, Jiangsu University of Technology, Changzhou, 213000, China

Hydro-viscous drive (HVD) clutch is a type of power transmission device by using shear stress of oil film. Whether the oil film between friction pair are uniformly distributed is the key factor that affecting the perfor-mance of HVD clutch. However, it is hard to make sure that the uniformity of oil film between friction pair are the same, which can lead to uneven wear problem for the frictional plates of HVD clutch. In order to study the uniformity of oil film of HVD clutch, the distribution regularity of oil films between friction pair of HVD clutch is researched by establishing the mathematics model. and a new HVD clutch with double-piston structure is pro-posed, which can greatly improve the uniformity of oil film of HVD clutch.

Keywords: Hydro-viscous drive clutch, Distribution of oil film, Uniformity of oil film thickness, Double-piston structure
Grants and funding:

This work was supported by the Natural Science Foundation of Hunan Province of China (2021JJ30378), the Research Foundation of Education Bureau of Hunan Province of China (23A0620), and Postgraduate Research & Practice Innovation Program of Jiangsu Province (SJCX24_1779)

Received: September 6, 2024; Revised: November 27, 2024; Accepted: December 5, 2024; Prepublished online: December 5, 2024; Published: December 21, 2024  Show citation

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Liao X, Sun L, Kang S, Liu K, Zhu X, Zhao Y. Analysis of the Influencing Factors on the Oil Film Uniformity of Hydro-viscous Drive Clutch. Manufacturing Technology. 2024;24(6):992-1000. doi: 10.21062/mft.2024.100.
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    References

    1. CUI, H., LIAN, Z., LI, L., WANG, Q. (2018). Analysis of influencing factors on oil film shear torque of hydro-viscous drive. Industrial Lubrication Tribology, 70(7), 1169-1175. Go to original source...
    2. XIANG-PING, L. (2016). Study on the Jam Breakout Technology of Tunnel Boring Machine Cutterhead Driving System Based on Hydro-viscous Coupling mechanism. Zhejiang University, 50, 902-912.
    3. KARPENKO, M., BOGDEVIÈIUS, M. (2017). Review of energy-saving technologies in modern hydraulic drives. Go to original source...
    4. CUI, H., LIAN, Z., DENG, Y., WANG, Q. (2016). The research on characteristics of flow field and shear torque of oil film for a hydro-viscous drive. JFPS International Journal of Fluid Power System, 10(2), 9-17. Go to original source...
    5. CUI, J., TANG, H. (2024). A review on flow instability in the hydro-viscous drive. Physics of Fluids, 36(4). Go to original source...
    6. CUI, J., XIE, F., WANG, C., ZHANG, X., XUAN, R. (2015). Dynamic transmission characteristics during soft-start of a hydro-viscous drive considering fluid-inertia item. Tribology online, 10(1), 35-47. Go to original source...
    7. LI, Z., XIE, F., SUN, J., ZHU, J., ZHENG, X., GUO, X., WANG, Y., HUA, Y. (2020). Influence of structural parameters of friction pair on oil temperature rise in the hydro-viscous clutch. Industrial Lubrication Tribology, 72(1), 79-85. Go to original source...
    8. MENG, Q., HOU, Y., TRIBOLOGY. (2011). Experimental study on hydro-viscous drive speed-regulating start. Industrial lubrication, 63(4), 239-244. Go to original source...
    9. MENGQING-RUI, H.-F. (2009). Numerical simulation on transient behavior of hydro-viscous drive speed regulating start. Tribology, 29(5), 418-424.
    10. XIANG-PING, L., GUO-FANG, G., HE, W., TIAN-YU, Z. (2014). Dynamic Performance of Hydro-viscous Drive Clutch with Double-piston. Transactions of the Chinese Society for Agricultural Machinery, 45, 1-6.
    11. CUI, H., WANG, Q., LIAN, Z., LI, L. (2019). Theoretical model and experimental research on friction and torque characteristics of hydro-viscous drive in mixed friction stage. Chinese Journal of Mechanical Engineering, 32, 1-11. Go to original source...
    12. CUI, H., YAO, S., YAN, Q., FENG, S., LIU, Q. (2014). Mathematical model and experiment validation of fluid torque by shear stress under influence of fluid temperature in the hydro-viscous clutch. Chinese Journal of Mechanical Engineering, 27, 32-40. Go to original source...
    13. LIAO, X., ZHAO, Y., KANG, S., LIU, K., ZHU, X., SUN, L. (2024). Dynamic Analysis of the Propulsion Process of Tunnel Boring Machines. Manufacturing Technology, 24(3), 410-419. doi:10.21062/mft.2024.047 Go to original source...
    14. ZHENG, B., WANG, X., ZHANG, J. (2021). Structure Optimization Design for Brake Drum Based on Response Surface Methodology. Manufacturing Technology, 21(3), 413-420. doi:10.21062/mft.2021.045 Go to original source...
    15. HAIBO, X., XIAO, H., YANG, Z., ZHIBING, L., HUAYONG, Y. (2014). Application of hydro-viscous driver in TBM cutter-head driving technology. Journal of Mechanical Engineering, 50(21), 69-75. Go to original source...
    16. XIE, F., WU, D., TONG, Y., ZHANG, B., ZHU, J. (2017). Effects of structural parameters of oil groove on transmission characteristics of hydro-viscous clutch based on viscosity-temperature property of oil film. Industrial Lubrication Tribology, 69(5), 690-700. Go to original source...
    17. KO©TIALIKOVá, D., JANEKOVá, M., DUBCOVá, P., HULC, M. (2024). Thermal - Static Analysis of the Brake Disc in SolidWorks. Manufacturing Technology, 24(4), 588-593. doi:10.21062/mft.2024.061 Go to original source...
    18. HUANG, J., WEI, J., QIU, M. (2012). Laminar flow in the gap between two rotating parallel frictional plates in the hydro-viscous drive. Chinese Journal of Mechanical Engineering, 25(1), 144-152. Go to original source...
    19. NING, C. (2003). Theoretical and application researches on hydroviscous drive. Zhejiang University.
    20. XIE, F., HOU, Y. (2011). Oil film hydrodynamic load capacity of hydro-viscous drive with variable viscosity. Industrial Lubrication Tribology, 63(3), 210-215. Go to original source...
    21. YAN, Z. (2024). Static and Modal Analysis of the Wheel-side Reducer Cover Plate Based on ANSYS. Manufacturing Technology, 24(3), 483-491. doi:10.21062/mft.2024.046 Go to original source...
    22. YIN, X.-X., LIN, Y.-G., LI, W. (2015). Operating modes and control strategy for megawatt-scale hydro-viscous transmission-based continuously variable speed wind turbines. IEEE Transactions on Sustainable Energy, 6(4), 1553-1564. Go to original source...
    23. GUOFANG, G., XIANGPING, L., YI, L., DONG, H., XUELAN, Y., XIAOLIN, Y., HUAYONG, Y. (2014). CN102913562B.
    24. GUOFANG, G., XIANGPING, L., YI, L., DONG, H., XUELAN, Y., XIAOLIN, Y., HUAYONG, Y. (2015). CN102913562A.

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