Authors: Ahmed A. D. Sarhan, M. Sayuti, M. Hamdi

Abstract:

Nowadays, the demand for high product quality focuses extensive attention to the quality of machined surface. The (CNC) milling machine facilities provides a wide variety of parameters set-up, making the machining process on the glass excellent in manufacturing complicated special products compared to other machining processes. However, the application of grinding process on the CNC milling machine could be an ideal solution to improve the product quality, but adopting the right machining parameters is required. In glass milling operation, several machining parameters are considered to be significant in affecting surface roughness. These parameters include the lubrication pressure, spindle speed, feed rate and depth of cut. In this research work, a fuzzy logic model is offered to predict the surface roughness of a machined surface in glass milling operation using CBN grinding tool. Four membership functions are allocated to be connected with each input of the model. The predicted results achieved via fuzzy logic model are compared to the experimental result. The result demonstrated settlement between the fuzzy model and experimental results with the 93.103% accuracy.

Keywords: CNC-machine, Glass milling, Grinding, Surface roughness, Cutting force, Fuzzy logic model.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1331911

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References:

[1] L, B.E., Glass: Mechanics and Technology. 2007: Wiley-VCH.
[2] R, D. and N. Y, Handbook of semiconductor manufacturing technology. 2007: CRC Press.
[3] L, Y. and H. H, Brittle materials in nano-abrasive fabrication of optical mirror-surface. Precision Engineering, 2008. 32: p. 336 - 341.
[4] W, Z.Z. and L.W. Y, Grinding of silicone and glass using a new dressing device and an improved lubrication system. Journal of Material and Manufacturing Processes, 2001. 16(4): p. 471-482.
[5] B, Z., Helical scan grinding of brittle and ductile materials. Journal of Materials Processing Technology, 1999. 91: p. 196-205.
[6] H, T.Y., C.J. C, and L.S. J, In-process surface recognition system based on neural networks in end milling cutting operations. Int. J. Mach. Tool Manuf., 1999. 39(4): p. 583-605.
[7] M, G., P. B, Coutris N, C.B. A, F. C, P. P, T.D. W, and B.K. D, A simple ballistic material model for soda-lime glass. International Journal of Impact Engineering, 2009. 36: p. 386-401.
[8] W, Z.Z., Surface finish of precision machined advanced materials. Journal of Material Processing Technology, 2002. 122: p. 173-178.
[9] Sayuti, M., Ahmed A.D. Sarhan, M. Fadzil, and M. Hamdi, Enhancement and verification of a machined surface quality for glass milling operation-using CBN grinding tool- Taguchi approach. International Journal of Advanced Manufacturing Technology, 2011.
[10] Zhang, J.Z., J.C. Chen, and E.D. Kirby, Surface roughness optimization in an end-milling operation using the Taguchi design method. Journal of Materials Processing Technology, 2007. 184(1-3): p. 233-239.
[11] Ghani, J.A., I.A. Choudhury, and H.H. Hassan, Application of Taguchi method in the optimization of end milling parameters. Journal of Materials Processing Technology, 2004. 145(1): p. 84-92.
[12] Zalnezhad, E., Ahmed A.D. Sarhan, and M. Hamdi, Optimizing the PVD TiN Thin Film Coating's parameters on Aerospace AL7075-T6 Alloy for Higher Coating Hardness and Adhesion with Better Tribological Properties of the Coating Surface. International Journal of Advanced Manufacturing Technology.
[13] Sayuti, M., Ahmed A.D. Sarhan, and M. Hamdi, Optimizing the Machining Parameters in Glass Grinding Operation on the CNC Milling Machine for Best Surface Roughness. Advance Material Research. , 2011. 154-155: p. 721-726.
[14] H, H., Machining characteristics and surface integrity of yytria stabilized tetragonal zirconia in high deep grinding. Material Science and Engineering, 2003. 345: p. 155 - 163.
[15] B, Y., S. X, and L. S, Mechanisms of edge chipping in laser-assisted milling of silicon nitride ceramics. International Journal of Machine Tools and Manufacture, 2009. 49: p. 344-350.
[16] Sarhan, A., R. Sayed, A.A. Nassr, and R.M. El-Zahry, Interrelationships between cutting force variation and tool wear in end-milling. Journal of Materials Processing Technology, 2001. 109: p. 229-235.
[17] Ahmed A.D. Sarhan, M.Sayuti, and M. Hamdi, Reduction of power and lubricant oil consumption in milling process using a new SiO2 nanolubrication system. International Journal of Advanced Manufacturing Technology, 2011 p. DOI: 10.1007/s00170-012-3940-7.
[18] Sonar, D.K., U.S. Dixit, and D.K. Ojha, The application of a radial basis function neural network for predicting the surface roughness in a turning process. The International Journal of Advanced Manufacturing Technology, 2006. 27(7): p. 661-666.
[19] Shamshirband, S., S. Kalantari, and Z. Bakhshandeh, Designing a smart multi-agent system based on fuzzy logic to improve the gas consumption pattern. Scientific Research and Essays 2010. Vol. 5(6): p. 592-605.
[20] Jaya, A.S.M., S.Z.M. Hashim, and M.N.A. Rahman. Fuzzy logic-based for predicting roughness performance of TiAlN coating. in Intelligent Systems Design and Applications (ISDA), 2010 10th International Conference on. 2010.
[21] Leung, R.W.K., H.C.W. Lau, and C.K. Kwong, An expert system to support the optimization of ion plating process: an OLAP-based fuzzycum- GA approach. Expert Systems with Applications, 2003. 25(3): p. 313-330.
[22] Oktem, H., T. Erzurumlu, and F. Erzincanli, Prediction of minimum surface roughness in end milling mold parts using neural network and genetic algorithm. Materials & Design, 2006. 27(9): p. 735-744.
[23] Chandrasekaran, M., M. Muralidhar, C. Krishna, and U. Dixit, Application of soft computing techniques in machining performance prediction and optimization: a literature review. The International Journal of Advanced Manufacturing Technology, 2010. 46(5): p. 445- 464.
[24] Hashmi, K., I.D. Graham, and B. Mills, Data selection for turning carbon steel using a fuzzy logic approach. Journal of Materials Processing Technology, 2003. 135(1): p. 44-58.