Simulation and Experiment Study of Heat Dissipation of Heavy-Duty Vertical Lathe Faceplate

Xiao Dong Yang; Bing Wei Gao; Wan Cao Lei; Yan Qin Zhang; Liang Yu; Dong Wang; Zhong Qi Li

doi:10.4028/www.scientific.net/KEM.621.425

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 621Simulation and Experiment Study of Heat...

Simulation and Experiment Study of Heat Dissipation of Heavy-Duty Vertical Lathe Faceplate

Abstract:

In order to obtain the heat dissipation regularity of heavy-duty vertical lathe faceplate with a large radius, mathematical model of convection heat transfer is established. According to the model, convection heat transfer process of the faceplate is analyzed at the velocity of 10~80rpm. The results show that velocity increasing not only impacts a greater influence on the temperature rising of hydrostatic bearing than the temperature rising of faceplate, but also drives the heat increased the heat dissipation, degenerated the heat concentration phenomenon. Experimental results shows consistent to the faceplate temperature numerical simulation results, the maximum error is 5%, which indicating that the numerical results conform physical regularities, the heat transfer mathematical model extends the range of applications of rotation convection heat transfer, so that vertical lathe heat dissipation situation analysis can be easier and more accurate.

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Periodical:

Key Engineering Materials (Volume 621)

Pages:

425-430

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.621.425

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Online since:

August 2014

Authors:

Xiao Dong Yang*, Bing Wei Gao, Wan Cao Lei, Yan Qin Zhang, Liang Yu, Dong Wang, Zhong Qi Li

Keywords:

Heavy Vertical Lathe, Temperature Distribution, Temperature Measurement Experiment, Workbench

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