Experimental determination of Optimum exchanged diameter in internal grinding

International Journal of Mechanical Engineering
© 2018 by SSRG - IJME Journal
Volume 5 Issue 1
Year of Publication : 2018
Authors : Le Xuan Hung, Vu Ngoc Pi, Ho Ky Thanh, Dang Thi Thanh Nga, Banh Tien Long
: 10.14445/23488360/IJME-V5I1P106
pdf
Citation:
MLA Style:

Le Xuan Hung, Vu Ngoc Pi, Ho Ky Thanh, Dang Thi Thanh Nga, Banh Tien Long, "Experimental determination of Optimum exchanged diameter in internal grinding" SSRG International Journal of Mechanical Engineering 5.1 (2018): 31-34.

APA Style:

Le Xuan Hung, Vu Ngoc Pi, Ho Ky Thanh, Dang Thi Thanh Nga, Banh Tien Long,(2018). Experimental determination of Optimum exchanged diameter in internal grinding. SSRG International Journal of Mechanical Engineering 5(1), 31-34.

Abstract:

This paper introduces an experimental study for determination of optimum exchanged diameter in internal grinding process. In the study, a cost structure for internal grinding was given. In the cost structure, the influences of grinding process parameters including the wheel life, the total dressing depth, the radial grinding wheel wear per dress and the initial grinding wheel diameter on the exchanged grinding wheel diameter were taken into account. Also, the influences of cost components including the machine tool hourly rate and the grinding wheel cost were investigated. Based on the cost structure, the set up and the procedure of the experiment for determining the optimum exchanged diameter was given. From the results of the experiment, the optimum exchanged grinding wheel diameter was found. Grinding with the optimum exchanged diameter, both the grinding cost and grinding time can be reduced considerably.

References:

[1] J. Peters, R. Aerens, Optimization Procedure of Three Phase Grinding Cycles of a Series without Intermediate Dressing, CIRP Annals - Manufacturing Technology, Volume 29, Issue 1, 1980, Pages 195-200.
[2] G. F. Li, L. S. Wang, L. B. Yang, Multi-parameter optimization and control of the cylindrical grinding process, Journal of Materials Processing Technology, Volume 129, Issues 1-3, 11 October 2002, Pages 232-236.
[3] R. Gupta, K. S. Shishodia, G. S. Sekhon, Optimization of grinding process parameters using enumeration method, Journal of Materials Processing Technology, Volume 112, Issue 1, 3 May 2001, P. 63-67.
[4] Y. C. Fu, H. J. Xu, J. H. Xu, Optimization design of grinding wheel topography for high efficiency grinding, Journal of Materials Processing Technology, Volume 129, Issues 1-3, 11 October 2002, Pages 118-122.
[5] Vu Ngoc Pi, Phan Quang The, Vu Hong Khiem, Nguyen Ngoc Huong, Cost optimization of external cylindrical grinding, Applied Mechanics and Materials, Vols. 312 (2013), pp. 982-989.
[6] X.M. Wen, A.A.O. Tay, A.Y.C. Nee, Micro-computer-based optimization of the surface grinding process, Journal of Materials Processing Technology, Volume 29, Issues 1-3, January 1992, P. 75-90.
[7] Aliuru Gopala Krishna, K. Mallikarjuna Rao, Multi-objective optimisation of surface grinding operations using scatter search approach, International Journal of Advanced Manufacturing Technology (2006) Vol. 29, pp. 475-480.
[8] Vu Ngoc Pi, Le Xuan Hung, Luu Anh Tung, Banh Tien Long, Cost optimization of Surface Grinding process, Journal of Environmental Science and Engineering A 5 (2016) 606-611.
[9] I. Inasaki, Monitoring and Optimization of Internal Grinding Process, CIRP Annals - Manufacturing Technology, Volume 40, Issue 1, 1991, Pages 359-362.
[10] G. Xiao, S. Malkin, On-Line Optimization for Internal Plunge Grinding, CIRP Annals – Manufacturing Technology, Volume 45, Issue 1, 1996, Pages 287-292.
[11] H.K. Tönshoff, A. Walter, Self-tuning fuzzy-controller for process control in internal grinding, Fuzzy Sets and Systems, Volume 63, Issue 3, 10 May 1994, Pages 359-373.
[12] Vu Ngoc Pi, Le Xuan Hung, Luu Anh Tung, Banh Tien Long, Cost optimization of Internal Grinding, Journal of Materials Science and Engineering B 6 (11-12) (2016) 291-296.
[13] W. Brian Rowe, Principle of Modern Grinding Technology, William Andrew, 2009.

Key Words:

Grinding process, internal grinding, grinding, cost optimization