Experimental Research on the Mathematical Model of Abrasion Ratio Based on the Abrasive Belt Grinding

G.J. Xiao; Y. Huang; R.K. Cheng; Y. Lu

doi:10.4028/www.scientific.net/AMM.328.480

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 328Experimental Research on the Mathematical Model of...

Experimental Research on the Mathematical Model of Abrasion Ratio Based on the Abrasive Belt Grinding

Abstract:

Abrasion ratio is an important parameter to estimate the wear resistance of abrasive belt grinding, reacting the relationship between the material removal and the abrasive belt wear, and also, its value is an important basis to instruct the process of abrasive belt grinding. The mathematical model of material removal is obtained by analyzing the basic mechanism theory of centerless cylindrical grinding in this paper, and the impact curve which react the relationship between the abrasion ration and the material removal or cutting depth is obtained by using the software of Mathematica. The abrasion ratio is testified in this paper by the experiment test of abrasive belt grinding for the titanium alloy, 45# steel and 304# stainless steel, systematic analyzing the affection of abrasion ratio on the hardness ratio and the belt speed. Experimental result shows that: belt speed is superior than hardness ratio to the abrasion ratio, and the mathematical model of material removal is testified by this experimental research. So the mathematical model of material removal could be used with theoretical basis in belt grinding process.

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Periodical:

Applied Mechanics and Materials (Volume 328)

Pages:

480-485

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.328.480

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Online since:

June 2013

Authors:

G.J. Xiao, Y. Huang, R.K. Cheng, Y. Lu

Keywords:

Abrasion Ratio, Abrasive Belt Grinding, Material Removal, Simulation Analysis, Wear

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References

[1] Y. Huang, Z. Huang: Modern abrasive belt grinding technology and engineering applications (Chongqing University Publication, 2008).

Google Scholar

[2] Z.N. Wang, H. Guo, Z.L. Sun: Diamand & Abrasives Engineering, Vol.2 (2008), pp.47-49.

Google Scholar

[3] T. Jia, M. Li, H.T. Zhang: Diamand & Abrasives Engineering, Vol. 2(2008), pp.47-49.

Google Scholar

[4] Y.H. Chai, T.L. Luo, P.W. Z: Journal of the Hebei Academy of Sciences Vol. 23(1), pp.50-53.

Google Scholar

[5] G.M. Zhang, F. Peng: Diamand & Abrasives Engineering Vol. 2(2005), pp.53-55.

Google Scholar

[6] D. Marinescu: Tribology of Abrasuve Machining Processes (William Andrew, Inc. Publications, the United States of America 2004).

Google Scholar

[7] Y. Huang, C.Q. Yang: China Mechanical Engineering, Vol. 22(3),pp.291-295.

Google Scholar

[8] Minori N, Mamoru K: Journal of Japan Society of Lubrication Engineers, Vol. 6(5), pp.157-162.

Google Scholar

[9] Bigerelle M, Najjar D: Journal of Japan Material Science, Vol. 38(11), pp.2525-2536.

Google Scholar

[10] Gajendra P S, Alphonsa J: Surface & Coatings Technology, Vol. 200(2006), pp.5807-5811.

Google Scholar

[11] Y. Huang, Z. Huang: China Mechanical Engineering, Vol.18(18), pp.2263-2267.

Google Scholar

[12] Jourani A, Dursapt M: Wear, Vol. 259(2005), pp.1137-1143.

Google Scholar