Thermomechanical Coupled Analysis of Multidisc Friction Pairs in Hydro-Viscous Drive

Jian Zhong Cui; Cun Tang Wang; Fang Wei Xie

doi:10.4028/www.scientific.net/AMR.941-944.2500

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 941-944Thermomechanical Coupled Analysis of Multidisc...

Thermomechanical Coupled Analysis of Multidisc Friction Pairs in Hydro-Viscous Drive

Abstract:

A transient temperature-stress coupled analysis is performed to investigate the thermomechanical coupled analysis of multidisc friction pairs in Hydro-viscous drive under simulated operation conditions. The normal pressure on all the surfaces are obtained from the principle of force equilibrium and then the heat flux acting on the related surface are also deduced. Based on the finite element method, the 3-D transient thermal and thermomechanical models of single pair are established as the typical one. The distribution of thermal and thermomechanical behavior during the soft-start can be studied. The results show that the maximum temperature occurs at the center of each subregion, where hot spots can be observed. The minimum hoop stress distribution can be observed in the separator disk.

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Periodical:

Advanced Materials Research (Volumes 941-944)

Pages:

2500-2503

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.941-944.2500

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Online since:

June 2014

Authors:

Jian Zhong Cui*, Cun Tang Wang, Fang Wei Xie

Keywords:

Heat Flux, Hydro-Viscous Drive, Multidisc Friction Pairs, Thermal Behavior, Thermomechanical Analysis

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References

[1] Chenguan Wei, Jiaxiang Zhao: Hydro-viscous Drive Technology (Defense Industry Press, China 1996).

Google Scholar

[2] Jang J. Y., Khonsari M. M.: ASME J. Tribol., Vol. 121 (1999), p.610.

Google Scholar

[3] T. C. Jen, Daniel James Nemecek: Int. J. Heat and Mass Transfer, Vol. 51 (2008), p.1757.

Google Scholar

[4] P. Zagrodzki: Wear, Vol. 140 (1990), p.291.

Google Scholar

[5] Tatara, R. A., and P. Payvar: Numerical Heat Transfer, Part A: Applications, Vol. 42 (2002), p.215.

Google Scholar

[6] Pär Marklund, Mäki R, Jang J, Khonsari M. M., Larsson R, et. al.: Tribology international, Vol. 40 (2007), p.876.

Google Scholar

[7] Masatoshi Miyagawa, Masataka Ogawa: Tribology Online, Vol. 4 (2009), p.17.

Google Scholar

[8] Hu jibin, Peng Zengxiong, Yuan Shihua: Chinese Journal of Mechanical Engineering, Vol. 22 (2009), p.238.

Google Scholar

[9] Hu Jibin, Wei Chao, Li Xueyuan: Tribology International, Vol. 62 (2013), p.8.

Google Scholar

[10] Zhao Shuangmei, Hilmas E. Gregory, Dharani R. Lokeswarappa: Wear, Vol. 264 (2008), p.1059.

Google Scholar

[11] Ingram M., Reddyhoff T., Spikes H.: Tribology Letters, Vol. 41 (2011), p.23.

Google Scholar

[12] Patir N., Cheng H. S.: Journal of lubrication Technology, Vol. 100 (1978), p.12.

Google Scholar

[13] P. Zagrodzki: Wear, Vol. 101 (1985), p.255.

Google Scholar