How to cite this paper
Sahoo, A & Sahoo, B. (2011). Surface roughness model and parametric optimization in finish turning using coated carbide insert: Response surface methodology and Taguchi approach.International Journal of Industrial Engineering Computations , 2(4), 819-830.
Refrences
Abdullah, A. (1996). Machining of aluminium based metal matrix composite (MMC), Ph.D Thesis, University of Warwick, Warwick, UK.
Aggarwal, A., Singh, H., Kumar, P., & Singh, M. (2008). Optimizing power consumption for CNC turned parts using response surface methodology and Taguchi’s technique—A comparative analysis. Journal of materials processing technology, 200, 373–384.
Choudhury, I.A., & El-Baradie, M.A. (1997). Surface roughness prediction in the turning of high-strength steel by factorial design of experiments. Journal of Materials Processing Technology, 67, 55-61.
Coldwell, H., Woods, R., Paul, M., Koshy, Ph. Dewes, R., & and Aspinwall, D. (2003). Rapid machining of hardened AISI H13 and D2 moulds, dies and press tools. Journal of Materials Processing Technology, 135, 301–311.
Davim, J.P. (2001). A note on the determination of optimal cutting conditions for surface finish obtained in turning using design of experiment. Journal of Materials Processing Technology, 116, 305-308.
Fisher, A. (1925). Statistical Methods for Research Worker, Oliver & Boyd, London.
Imbeni, V., Martini, C., Lanzoni, E., Poli, G. and Hutchings, I.M. (2001). Tribological behaviour of multi-layered PVD nitride coatings. Wear, 251, 997-1002.
Isakov, E. (2009). Cutting data for turning steel. Industrial press, New York, USA, 104.
Isik, Y. (2007). Investigating the machinability of tool steels in turning operations. Materials and Design, 28, 1417–1424.
Klocke, F., & Krieg, T. (1999). Coated tools for metal cutting-features and applications. Annals of CIRP, 48(2), 1-11.
Lin, V.S., Lee, B.Y., & Wu, C.L. (2001). Modeling the surface roughness and cutting force for turning. Journal of Materials Processing Technology, 108, 286-293.
Montgomery D.C. (1991). Design and analysis of experiments, John Wiley and Sons, NewYork.
Nalbant, M., Gokkaya, H., & Sur, G. (2007). Application of Taguchi method in the optimization of cutting parameters for surface roughness in turning. Materials and Design, 28, 1379-1385.
Nian, C.Y., Yang, W.H., & Tarng, Y.S. (1999). Optimization of turning operations with multiple performance characteristics. Journal of Materials Processing Technology, 95, 90-96.
Noordin, M. Y., Tang, Y. C., & Kurniawan, D. (2007). The use of TiALN coated carbide tool when finish machining hardened stainless steel. International Journal of Precision Technology, 1(1), 21-29.
Phadke, M.S. (1989). Quality engineering using robust design, Englewood Cliffs, NJ:Prentice-Hall.
Ross, P.J. (1996). Taguchi Techniques for Quality Engineering, McGraw-Hill, New York.
Sahin, Y., & Motorcu, R. A. (2005). Surface roughness model for machining mild steel with coated carbide tool. Materials and Design, 26, 321–326.
Singh, H., & Kumar, P. (2007). Mathematical models of tool life &surface roughness for turning operation through response surface methodology. Journal of scientific & industrial research, 66, 220-226.
Stappen, V.M., Stals, L.M., Kerkhofs, M. and Quaeyhaegens, C. (1995). State of the art for the industrial use of ceramic PVD coatings. Surface and Coatings Technology, 74/75, 629-633.
Thomas, M., Beauchamp, Y., Youssef, Y.A., Masounave, J. (1997). An experimental design for surface roughness and built-up-edge formation in lathe dry turning. International Journal of Quality Science, 2 (3), 167-180.
Wallbank, J. (1991). Development in tool materials, advanced machining for quality and productivity, Proceedings of the second international conference on behaviour of materials in Machining. York, UK, Nov 14-15.
Yang, W.H. and Tarng, Y.S. (1998). Design optimization of cutting parameters for turning operations based on Taguchi method. Journal of Materials Processing Technology, 84, 112-129.
YİĞİT, R. FINDIK, F., & ÇELİK, E. (2009). Performance of multilayer coated carbide tools when turning cast iron. Turkish Journal of Engineering Environment Sciences, 33, 147-157.
Aggarwal, A., Singh, H., Kumar, P., & Singh, M. (2008). Optimizing power consumption for CNC turned parts using response surface methodology and Taguchi’s technique—A comparative analysis. Journal of materials processing technology, 200, 373–384.
Choudhury, I.A., & El-Baradie, M.A. (1997). Surface roughness prediction in the turning of high-strength steel by factorial design of experiments. Journal of Materials Processing Technology, 67, 55-61.
Coldwell, H., Woods, R., Paul, M., Koshy, Ph. Dewes, R., & and Aspinwall, D. (2003). Rapid machining of hardened AISI H13 and D2 moulds, dies and press tools. Journal of Materials Processing Technology, 135, 301–311.
Davim, J.P. (2001). A note on the determination of optimal cutting conditions for surface finish obtained in turning using design of experiment. Journal of Materials Processing Technology, 116, 305-308.
Fisher, A. (1925). Statistical Methods for Research Worker, Oliver & Boyd, London.
Imbeni, V., Martini, C., Lanzoni, E., Poli, G. and Hutchings, I.M. (2001). Tribological behaviour of multi-layered PVD nitride coatings. Wear, 251, 997-1002.
Isakov, E. (2009). Cutting data for turning steel. Industrial press, New York, USA, 104.
Isik, Y. (2007). Investigating the machinability of tool steels in turning operations. Materials and Design, 28, 1417–1424.
Klocke, F., & Krieg, T. (1999). Coated tools for metal cutting-features and applications. Annals of CIRP, 48(2), 1-11.
Lin, V.S., Lee, B.Y., & Wu, C.L. (2001). Modeling the surface roughness and cutting force for turning. Journal of Materials Processing Technology, 108, 286-293.
Montgomery D.C. (1991). Design and analysis of experiments, John Wiley and Sons, NewYork.
Nalbant, M., Gokkaya, H., & Sur, G. (2007). Application of Taguchi method in the optimization of cutting parameters for surface roughness in turning. Materials and Design, 28, 1379-1385.
Nian, C.Y., Yang, W.H., & Tarng, Y.S. (1999). Optimization of turning operations with multiple performance characteristics. Journal of Materials Processing Technology, 95, 90-96.
Noordin, M. Y., Tang, Y. C., & Kurniawan, D. (2007). The use of TiALN coated carbide tool when finish machining hardened stainless steel. International Journal of Precision Technology, 1(1), 21-29.
Phadke, M.S. (1989). Quality engineering using robust design, Englewood Cliffs, NJ:Prentice-Hall.
Ross, P.J. (1996). Taguchi Techniques for Quality Engineering, McGraw-Hill, New York.
Sahin, Y., & Motorcu, R. A. (2005). Surface roughness model for machining mild steel with coated carbide tool. Materials and Design, 26, 321–326.
Singh, H., & Kumar, P. (2007). Mathematical models of tool life &surface roughness for turning operation through response surface methodology. Journal of scientific & industrial research, 66, 220-226.
Stappen, V.M., Stals, L.M., Kerkhofs, M. and Quaeyhaegens, C. (1995). State of the art for the industrial use of ceramic PVD coatings. Surface and Coatings Technology, 74/75, 629-633.
Thomas, M., Beauchamp, Y., Youssef, Y.A., Masounave, J. (1997). An experimental design for surface roughness and built-up-edge formation in lathe dry turning. International Journal of Quality Science, 2 (3), 167-180.
Wallbank, J. (1991). Development in tool materials, advanced machining for quality and productivity, Proceedings of the second international conference on behaviour of materials in Machining. York, UK, Nov 14-15.
Yang, W.H. and Tarng, Y.S. (1998). Design optimization of cutting parameters for turning operations based on Taguchi method. Journal of Materials Processing Technology, 84, 112-129.
YİĞİT, R. FINDIK, F., & ÇELİK, E. (2009). Performance of multilayer coated carbide tools when turning cast iron. Turkish Journal of Engineering Environment Sciences, 33, 147-157.