How to cite this paper
Kumar, R., Sahoo, A., Satyanarayana, K & Rao, G. (2013). Some studies on cutting force and temperature in machining Ti-6Al-4V alloy using regression analysis and ANOVA.International Journal of Industrial Engineering Computations , 4(3), 427-436.
Refrences
Ali, M.H., Khidhir, B.A., Mohamed, B, & Oshkour, A.A. (2012). Prediction of high cutting speed parameters for Ti-6Al-4V by using Finite Element Modeling. International Journal of Modeling and Optimization, 2 (1), 31-45.
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.
Che Haron, C. H., Ghani, J. A., & Ibrahim, G. A. (2007). Surface integrity of AISI D2 when turned using coated and uncoated carbide tools. International Journal of Precision Technology, 1(1), 106-114.
Iqbal, SA., Mativenga, PT. & Sheikh, MA. (2008). A sensitivity study of the effects of interface heat transfer coefficient on FE modeling of machining process for a wide range of cutting speeds, The 6th international conference on manufacturing research, Brunel university, UK.
Iqbal, SA., Mativenga, PT., & Sheikh, MA. (2009). An investigative study of the interface heat transfer coefficient for FE modeling of high speed machining. NED University Journal of Research, 6 (1), 44-56.
Jangra, K., Grover, S., & Aggarwal, A. (2011). Simultaneous optimization of material removal rate and surface roughness for WEDM of WCCo composite using grey relational analysis along with Taguchi method. International Journal of Industrial Engineering Computations, 2, 479-490.
Kosaraju, S., Anne, VG., & Popuri, BB. (2012). Taguchi analysis on cutting forces and temperature in turning titanium Ti-6Al-4V. International Journal of Mechanical and Industrial Engineering, 1 (4), 2231- 6477.
Kumar, R., Sahoo, A.K., & Kosaraju, S. (2013). Finite element simulation of forces and temperature in turning of titanium alloy using Deform 3D. International journal of mechanical engineering & research, 3(5), 330-334.
Lalwani, DI., Mehta, NK. & Jain, PK. (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.
Mohamed, A., Dabnun, M.S.J. Hashmi & El-Baradie, MA. (2005). Surface roughness prediction model by design of experiments for turning machinable glass–ceramic (Macor). Journal of Materials Processing Technology, 164-165, 1289-1293.
More, AS., Jiang, W., Brown, WD. & Malshe, AP. (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.
Ozel, T., & Zeren, E., (2006). A Methodology to determine work material flow stress and tool-chip interfacial properties by using analysis of machining. Journal of Manufacturing Science and Engineering, 128, 119-129.
Puertas Arbizu, I. & Luis Pérez, CJ. (2003). Surface roughness prediction by factorial design of experiments in turning processes. Journal of Materials Processing Technology, 143-144, 390-396.
Sahoo, AK., & 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 (8), 2153-2165.
Sahoo, AK., & Sahoo, B. (2012). Performance studies of multilayer hard surface coatings (TiN/TiCN/Al2O3/TiN) of indexable carbide inserts in hard machining: Part-II (RSM, grey relational and techno economical approach), Measurement, http://dx.doi.org/10.1016/j.measurement.2012.09.023.
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.
Singh, H., & Kumar, P. (2006). Optimizing feed force for turned parts through the Taguchi Technique. Sadhana, 31 (6), 671-681.
Singh, D. & Rao, PV. (2007). A surface roughness prediction model for hard turning process, International Journal of Advanced Manufacturing Technology, 32 (11-12), 1115-1124.
Sun, S., Brandt, M., & Dargusch, MS. (2009). Characteristic of cutting forces and chip formation in cutting of titanium alloys, Internal Journal of machine tools & manufacture, 49, 561-568.
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.
Upadhyay, V., Jain, PK., & Mehta, NK. (2012). In-process prediction of surface roughness in turning of Ti–6Al–4V alloy using cutting parameters and vibration signals, Measurement http://dx.doi.org/10.1016/j.measurement.2012.06.002.
Vijay Sekar, K. S., & Pradeep Kumar, M. (2011). Finite element simulations of Ti6Al4V titanium alloy machining to assess material model parameters of the Johnson-Cook constitutive equation. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 33(2), 203-211.
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.
Che Haron, C. H., Ghani, J. A., & Ibrahim, G. A. (2007). Surface integrity of AISI D2 when turned using coated and uncoated carbide tools. International Journal of Precision Technology, 1(1), 106-114.
Iqbal, SA., Mativenga, PT. & Sheikh, MA. (2008). A sensitivity study of the effects of interface heat transfer coefficient on FE modeling of machining process for a wide range of cutting speeds, The 6th international conference on manufacturing research, Brunel university, UK.
Iqbal, SA., Mativenga, PT., & Sheikh, MA. (2009). An investigative study of the interface heat transfer coefficient for FE modeling of high speed machining. NED University Journal of Research, 6 (1), 44-56.
Jangra, K., Grover, S., & Aggarwal, A. (2011). Simultaneous optimization of material removal rate and surface roughness for WEDM of WCCo composite using grey relational analysis along with Taguchi method. International Journal of Industrial Engineering Computations, 2, 479-490.
Kosaraju, S., Anne, VG., & Popuri, BB. (2012). Taguchi analysis on cutting forces and temperature in turning titanium Ti-6Al-4V. International Journal of Mechanical and Industrial Engineering, 1 (4), 2231- 6477.
Kumar, R., Sahoo, A.K., & Kosaraju, S. (2013). Finite element simulation of forces and temperature in turning of titanium alloy using Deform 3D. International journal of mechanical engineering & research, 3(5), 330-334.
Lalwani, DI., Mehta, NK. & Jain, PK. (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.
Mohamed, A., Dabnun, M.S.J. Hashmi & El-Baradie, MA. (2005). Surface roughness prediction model by design of experiments for turning machinable glass–ceramic (Macor). Journal of Materials Processing Technology, 164-165, 1289-1293.
More, AS., Jiang, W., Brown, WD. & Malshe, AP. (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.
Ozel, T., & Zeren, E., (2006). A Methodology to determine work material flow stress and tool-chip interfacial properties by using analysis of machining. Journal of Manufacturing Science and Engineering, 128, 119-129.
Puertas Arbizu, I. & Luis Pérez, CJ. (2003). Surface roughness prediction by factorial design of experiments in turning processes. Journal of Materials Processing Technology, 143-144, 390-396.
Sahoo, AK., & 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 (8), 2153-2165.
Sahoo, AK., & Sahoo, B. (2012). Performance studies of multilayer hard surface coatings (TiN/TiCN/Al2O3/TiN) of indexable carbide inserts in hard machining: Part-II (RSM, grey relational and techno economical approach), Measurement, http://dx.doi.org/10.1016/j.measurement.2012.09.023.
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.
Singh, H., & Kumar, P. (2006). Optimizing feed force for turned parts through the Taguchi Technique. Sadhana, 31 (6), 671-681.
Singh, D. & Rao, PV. (2007). A surface roughness prediction model for hard turning process, International Journal of Advanced Manufacturing Technology, 32 (11-12), 1115-1124.
Sun, S., Brandt, M., & Dargusch, MS. (2009). Characteristic of cutting forces and chip formation in cutting of titanium alloys, Internal Journal of machine tools & manufacture, 49, 561-568.
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.
Upadhyay, V., Jain, PK., & Mehta, NK. (2012). In-process prediction of surface roughness in turning of Ti–6Al–4V alloy using cutting parameters and vibration signals, Measurement http://dx.doi.org/10.1016/j.measurement.2012.06.002.
Vijay Sekar, K. S., & Pradeep Kumar, M. (2011). Finite element simulations of Ti6Al4V titanium alloy machining to assess material model parameters of the Johnson-Cook constitutive equation. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 33(2), 203-211.