How to cite this paper
Sahoo, A., Orra, K & Routra, B. (2013). Application of response surface methodology on investigating flank wear in machining hardened steel using PVD TiN coated mixed ceramic insert.International Journal of Industrial Engineering Computations , 4(4), 469-478.
Refrences
Aggarwala, A., Singh, K., 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.
Al-Ahmari, A.M.A. (2007). Predictive machinability models for a selected hard material in turning operations. Journal of Materials Processing Technology, 190, 305-311.
Basak, S., Dixit, U.S., & Davim, J.P. (2007). Application of radial basis function neural networks in optimization of hard turning of AISI D2 cold-worked tool steel with a ceramic tool. Proc. IMechE, Part B: Journal of Engineering Manufacture, 221, 987-998.
Bhattacharya, A., Das, S., Majumder, P., & Batish, A. (2009). Estimating the effect of cutting parameters on surface finish and power consumption during high speed machining of AISI 1045 steel using Taguchi design and ANOVA. Production Engineering, 3(1), 31-40.
Cemal Cakir, M., Ensarioglu, C., & Demirayak, I. (2009). Mathematical modeling of surface roughness for evaluating the effects of cutting parameters and coating material. Journal of Materials Processing Technology, 209 (1), 102-109.
Chien, W-T., & Tsai, C-S. (2003). The investigation on the prediction of tool wear and the determination of optimum cutting conditions in machining 17-4PH stainless steel. Journal of Materials Processing Technology, 140, 340-345.
Horng, J-T., Liu, N-M., & Chiang, K. (2008). Investigating the machinability evaluation of Hadfield steel in the hard turning with Al2O3/TiC mixed ceramic tool based on the response surface methodology. Journal of Materials Processing Technology, 208 (1-3), 532-541.
Horng, J-T., Liu, N-M., & Chiang, K-T. (2008). Investigating the machinability evaluation of Hadfield steel in the hard turning with Al2O3/TiC mixed ceramic tool based on the response surface methodology. Journal of Materials Processing Technology, 208 (1-3), 532-541.
Huang, Y., Kevin Chou, Y., & Liang, S.Y. (2007). CBN tool wear in hard turning: a survey on research progresses. International Journal of Advanced Manufacturing Technology, 35, 443-453.
Lalwani, D.I., Mehta, N.K., & Jain, P.K. (2008). Experimental investigations of cutting parameters influence on cutting forces and surface roughness in finish hard turning of MDN250 steel. Journal of Materials Processing Technology, 206 (1-3), 167-179.
Montgomery, D.C. (1997). Design and Analysis of Experiments, 4th ed. Wiley, New York.
More, A.S., Jiang, W., Brown, W.D., & Malshe, A.P. (2006). Tool wear and machining performance of cBN-TiN coated carbide inserts and PCBN compact inserts in turning AISI 4340 hardened steel. Journal of Materials Processing Technology, 180, 253-262.
O¨ zel, T., Karpat, Y., Figueira, L., & Davim, J.P. (2007). Modelling of surface finish and tool flank wear in turning of AISI D2 steel with ceramic wiper inserts. Journal of Materials Processing Technology, 189, 192-198.
Ozel, T., & Karpat, Y. (2005). Predictive modeling of surface roughness and tool wear in hard turning using regression and neural networks. International Journal of Machine Tools & Manufacture, 45, 467-479.
Paiva, A.P., Ferreira, J.R., & Balestrassi, P.P. (2007). A multivariate hybrid approach applied to AISI 52100 hardened steel turning optimization. Journal of Materials Processing Technology, 189, 26-35.
Quiza, R., Figueira, L., & Davim, J.P. (2008). Comparing statistical models and artificial neural networks on predicting the tool wear in hard machining D2 AISI steel. International Journal of Advanced Manufacturing Technology, 37, 641-648.
Sahoo, A.K., & Sahoo, B. (2012). Experimental investigations on machinability aspects in finish hard turning of AISI 4340 steel using uncoated and multilayer coated carbide inserts. Measurement, 45, 2153–2165.
Sahoo, A.K., & Sahoo, B. (2011). Mathematical modelling and multi-response optimisation using response surface methodology and grey based Taguchi method: an experimental investigation. Int. J. Experimental Design and Process Optimisation, 2(3), 221-242.
Sahoo, A.K. & 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, 819-830.
Sahoo, A.K., & Orra, K., Rout, A.K., & Routra, B.C. (2011). Multi-response optimization in machining hardened steel using Grey-based Taguchi method. International Journal of Manufacturing Technology and Industrial Engineering, 1(1), 7-12.
Sahoo, A.K., Pradhan, S., & Rout, A.K. (2013). Development and machinability assessment in turning Al/SiCp-metal matrix composite with multilayer coated carbide insert using Taguchi and statistical techniques. Archives of civil and mechanical engineering, 13, 27-35.
Sahoo, A.K., & Sahoo, B. (2013). Experimental investigation on flank wear and tool life, cost analysis and mathematical model in turning hardened steel using coated carbide inserts. International Journal of Industrial Engineering Computations, doi: 10.5267/j.ijiec.2013.05.003.
Sahin, Y., & Motorcu, A.R. (2008). Surface roughness model in machining hardened steel with cubic boron nitride cutting tool. International Journal of Refractory Metals & Hard Materials, 26, 84-90.
Singh, D., & Rao, P.V. (2007). A surface roughness prediction model for hard turning process, International Journal of Advanced Manufacturing Technology, 32, 1115-1124.
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.
Singh, D., & Rao, P.V. (2007). A surface roughness prediction model for hard turning process. International Journal of Advanced Manufacturing Technology, 32 (11-12), 1115-1124.
Tamizharasan, T., Selvaraj, T., & Noorul Haq, A. (2006). Analysis of tool wear and surface finish in hard turning. International Journal of Advanced Manufacturing Technology, 28, 671-679.
Thamizhmanii, S., & Hasan, S. (2008). Measurement of surface roughness and flank wear on hard martensitic stainless steel by CBN and PCBN cutting tools. Journal of Achievements in Materials and Manufacturing Engineering, 31 (2), 415-421.
Thangavel, P., & Selladurai, V. (2008). An experimental investigation on the effect of turning parameters on surface roughness. International Journal of Manufacturing Research, 3 (3), 285-300.
T?nshoff, H., Wobker, H., & Brandt, D. (1995). Hard turning - influences on the workpiece properties. Transactions of NAMRI/SME, 23, 215-220.
Yallese, M.A., Chaoui, K., Zeghib, N., Boulanouar, L., & Rigal, J-F. (2009). Hard machining of hardened bearing steel using cubic boron nitride tool. Journal of Materials Processing Technology, 209, 1092-1104.
Al-Ahmari, A.M.A. (2007). Predictive machinability models for a selected hard material in turning operations. Journal of Materials Processing Technology, 190, 305-311.
Basak, S., Dixit, U.S., & Davim, J.P. (2007). Application of radial basis function neural networks in optimization of hard turning of AISI D2 cold-worked tool steel with a ceramic tool. Proc. IMechE, Part B: Journal of Engineering Manufacture, 221, 987-998.
Bhattacharya, A., Das, S., Majumder, P., & Batish, A. (2009). Estimating the effect of cutting parameters on surface finish and power consumption during high speed machining of AISI 1045 steel using Taguchi design and ANOVA. Production Engineering, 3(1), 31-40.
Cemal Cakir, M., Ensarioglu, C., & Demirayak, I. (2009). Mathematical modeling of surface roughness for evaluating the effects of cutting parameters and coating material. Journal of Materials Processing Technology, 209 (1), 102-109.
Chien, W-T., & Tsai, C-S. (2003). The investigation on the prediction of tool wear and the determination of optimum cutting conditions in machining 17-4PH stainless steel. Journal of Materials Processing Technology, 140, 340-345.
Horng, J-T., Liu, N-M., & Chiang, K. (2008). Investigating the machinability evaluation of Hadfield steel in the hard turning with Al2O3/TiC mixed ceramic tool based on the response surface methodology. Journal of Materials Processing Technology, 208 (1-3), 532-541.
Horng, J-T., Liu, N-M., & Chiang, K-T. (2008). Investigating the machinability evaluation of Hadfield steel in the hard turning with Al2O3/TiC mixed ceramic tool based on the response surface methodology. Journal of Materials Processing Technology, 208 (1-3), 532-541.
Huang, Y., Kevin Chou, Y., & Liang, S.Y. (2007). CBN tool wear in hard turning: a survey on research progresses. International Journal of Advanced Manufacturing Technology, 35, 443-453.
Lalwani, D.I., Mehta, N.K., & Jain, P.K. (2008). Experimental investigations of cutting parameters influence on cutting forces and surface roughness in finish hard turning of MDN250 steel. Journal of Materials Processing Technology, 206 (1-3), 167-179.
Montgomery, D.C. (1997). Design and Analysis of Experiments, 4th ed. Wiley, New York.
More, A.S., Jiang, W., Brown, W.D., & Malshe, A.P. (2006). Tool wear and machining performance of cBN-TiN coated carbide inserts and PCBN compact inserts in turning AISI 4340 hardened steel. Journal of Materials Processing Technology, 180, 253-262.
O¨ zel, T., Karpat, Y., Figueira, L., & Davim, J.P. (2007). Modelling of surface finish and tool flank wear in turning of AISI D2 steel with ceramic wiper inserts. Journal of Materials Processing Technology, 189, 192-198.
Ozel, T., & Karpat, Y. (2005). Predictive modeling of surface roughness and tool wear in hard turning using regression and neural networks. International Journal of Machine Tools & Manufacture, 45, 467-479.
Paiva, A.P., Ferreira, J.R., & Balestrassi, P.P. (2007). A multivariate hybrid approach applied to AISI 52100 hardened steel turning optimization. Journal of Materials Processing Technology, 189, 26-35.
Quiza, R., Figueira, L., & Davim, J.P. (2008). Comparing statistical models and artificial neural networks on predicting the tool wear in hard machining D2 AISI steel. International Journal of Advanced Manufacturing Technology, 37, 641-648.
Sahoo, A.K., & Sahoo, B. (2012). Experimental investigations on machinability aspects in finish hard turning of AISI 4340 steel using uncoated and multilayer coated carbide inserts. Measurement, 45, 2153–2165.
Sahoo, A.K., & Sahoo, B. (2011). Mathematical modelling and multi-response optimisation using response surface methodology and grey based Taguchi method: an experimental investigation. Int. J. Experimental Design and Process Optimisation, 2(3), 221-242.
Sahoo, A.K. & 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, 819-830.
Sahoo, A.K., & Orra, K., Rout, A.K., & Routra, B.C. (2011). Multi-response optimization in machining hardened steel using Grey-based Taguchi method. International Journal of Manufacturing Technology and Industrial Engineering, 1(1), 7-12.
Sahoo, A.K., Pradhan, S., & Rout, A.K. (2013). Development and machinability assessment in turning Al/SiCp-metal matrix composite with multilayer coated carbide insert using Taguchi and statistical techniques. Archives of civil and mechanical engineering, 13, 27-35.
Sahoo, A.K., & Sahoo, B. (2013). Experimental investigation on flank wear and tool life, cost analysis and mathematical model in turning hardened steel using coated carbide inserts. International Journal of Industrial Engineering Computations, doi: 10.5267/j.ijiec.2013.05.003.
Sahin, Y., & Motorcu, A.R. (2008). Surface roughness model in machining hardened steel with cubic boron nitride cutting tool. International Journal of Refractory Metals & Hard Materials, 26, 84-90.
Singh, D., & Rao, P.V. (2007). A surface roughness prediction model for hard turning process, International Journal of Advanced Manufacturing Technology, 32, 1115-1124.
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.
Singh, D., & Rao, P.V. (2007). A surface roughness prediction model for hard turning process. International Journal of Advanced Manufacturing Technology, 32 (11-12), 1115-1124.
Tamizharasan, T., Selvaraj, T., & Noorul Haq, A. (2006). Analysis of tool wear and surface finish in hard turning. International Journal of Advanced Manufacturing Technology, 28, 671-679.
Thamizhmanii, S., & Hasan, S. (2008). Measurement of surface roughness and flank wear on hard martensitic stainless steel by CBN and PCBN cutting tools. Journal of Achievements in Materials and Manufacturing Engineering, 31 (2), 415-421.
Thangavel, P., & Selladurai, V. (2008). An experimental investigation on the effect of turning parameters on surface roughness. International Journal of Manufacturing Research, 3 (3), 285-300.
T?nshoff, H., Wobker, H., & Brandt, D. (1995). Hard turning - influences on the workpiece properties. Transactions of NAMRI/SME, 23, 215-220.
Yallese, M.A., Chaoui, K., Zeghib, N., Boulanouar, L., & Rigal, J-F. (2009). Hard machining of hardened bearing steel using cubic boron nitride tool. Journal of Materials Processing Technology, 209, 1092-1104.