How to cite this paper
Kumar, V., Kumar, V & Jangra, K. (2015). An experimental investigation and statistical modelling for trim cutting operation in WEDM of Nimonic-90.International Journal of Industrial Engineering Computations , 6(3), 351-364.
Refrences
Arunachalam, R.M., Mannan, M.A., & Spowage, A.C. (2004). Surface integrity when machining age hardened Inconel 718 with coated carbide cutting tools. International Journal of Machine Tools & Manufacture, 44(14), 1481-1491.
Bhuyan, B.K., & Yadava, V. (2014). Experimental Study of Travelling Wire Electrochemical Spark Machining of Borosilicate Glass. Materials and Manufacturing Processes, 29(3), 298-304.
Bobbili, R., Madhu, V., & Gogia, A.K. (2013).Effect of Wire-EDM Machining Parameters on Surface Roughness and Material Removal Rate of High Strength Armor Steel. Materials and Manufacturing Processes, 28(4), 364–368.
Cheng, X., Yang, X.H., Huang, Y.M., Zheng, G.M., & Li, L. (2014).Helical surface creation by wire electrical discharge machining for micro tools. Robotics and Computer-Integrated Manufacturing, 30(3), 287–294.
Choudhury, I.A., & El-Baradie, M.A. (1998). Machinability of nickel-base super alloys- a general review. Journal of Materials Processing Technology, 77(1-3), 278-284.
Cochran, G., & Cox, G.M. (1962). Experimental Design. Asia Publishing House, New Delhi.
Deringer, G., & Suich, R. (1980). Simultaneous optimization of several response variables. Journal of Quality Technology, 12(4), 214-219.
Ezugwu, E.O. (2005). Key improvements in the machining of difficult-to-cut aerospace alloys. International Journal of Machine Tools & Manufacture, 45(12-13), 1353-1367.
Guo, Y.B., Li, W., & Jawahir, I.S. (2009). Surface integrity characterization and prediction in machining of hardened and difficult-to-machine alloys-a state-of-art research review and analysis. Journal of Machine Science & Technology, 13(4), 437- 470.
Gupta, K., & Jain, N.K. (2014). Analysis and optimization of micro-geometry of miniature spur gears manufactured by wire electric discharge machining. Precision Engineering, 38(4), 728-737.
Han, F., Jiang, J., & Yu, D. (2007). Influence of machining parameters on surface roughness in finish cut of WEDM. International Journal of Advance Manufacturing Technology, 34(5-6), 538-546.
Hewidy, M.S., El-Taweel, T.A., & El-Safty, M.F. (2005). Modeling the machining parameters of wire electrical discharge machining of Inconel 601 using RSM. Journal of Materials Processing Technology, 169(2), 328–336.
Hood, R., Soo, S.L., Aspinwall, D.K., Andrews, P., & Sage, C. (2011). Twist drilling of Haynes 282 Superalloy, Procedia Engineering, 19, 150-155.
Huang, J.T., Liao, Y.S., & Hsue, W.J. (1999). Determination of finish- cutting operation and machining –parameters setting in wire electrical discharge machining. Journal of Materials Processing Technology, 87(1-3), 69-81.
Jangra, K., Grover, Chan FTS, & Aggarwal, A. (2011). A Digraph and matrix method to evaluate the machinability of tungsten carbide composite with wire EDM. International Journal of Advance Manufacturing Technology, 2(3), 959-974.
Jangra, K., Grover, S., & Aggarwal, A. (2011). Simultaneous optimization of material removal rate and surface roughness for WEDM of WC-Co composite using grey relational analysis along with Taguchi method. International Journal of Industrial Engineering Computations, 2(3), 479–490.
Jangra, K. (2012). Study of unmachined area in intricate machining after rough cut in WEDM. International Journal of Industrial Engineering Computations, 3(5), 887-892.
Jangra, K., & Grover, S. (2012). Modeling and experimental investigation of process parameters in WEDM of WC- 5.3% Co using response surface methodology. Mechanical Science, 3, 63-72.
Jangra, K.K., Kumar, V., Kumar, V. (2014). An experimental and comparative study on rough and trim cutting operation in WEDM of hard to machine materials. Procedia Materials Science, 5, 1603 – 1612.
Jangra, K.K. (2015). An experimental study for multi-pass cutting operation in wire electrical discharge machining of WC- 5.3% Co composite. International Journal of Advance Manufacturing Technology, 76, 971-982.
Khanna, R., & Singh, H. (2013) Performance analysis for D-3 material using response surface methodology on WEDM. International Journal of Machining and Machinability of Materials, 14, 45 – 65.
Klink, A., Guoa, Y.B., & Klocke, F. (2011).Surface integrity evolution of powder metallurgical tool steel by main cut and finishing trim cuts in wire-EDM. Procedia Engineering, 19, 178-183.
Kortabarria, A., Madariaga, A., Fernandez, E., Esnaola, J.A., & Arrazola, P.J. (2011).A comparative study of residual stress profiles on Inconel 718 induced by dry face turning, Procedia Engineering, 19, 228 – 234.
Krain, H.R., Sharman, A.R.C., & Ridgway, K. (2007). Optimisation of tool life and productivity when end milling Inconel 718 TM. Journal of Material Processing Technology, 189(1-3), 153-161.
Kumar, V., Jangra, K., & Kumar, V. (2012). Effect of WEDM parameters on machinability of Nimonic-90.Proceedings of the National Conference on Trends and Advances in Mechanical Engineering (TAME), YMCA University of Science and Technology, 511-516.
Lee, S.H., & Li, X.P. (2003).Study of the surface integrity of the machined workpiece in the EDM of tungsten carbide. Journal of Materials Processing Technology, 139(1-3), 315-321.
Li, L., Guo, Y.B., Wei, X. T., & Li, W. (2013). Surface integrity characteristics in wire-EDM of Inconel 718 at different discharge energy. Procedia CIRP, 6, 221 – 226.
Liao, Y.S., & Yu, Y.P. (2004). The energy aspect of material property in WEDM and its application. Journal of Materials Processing Technology, 149(1-3), 77–82.
Myers, R.H., & Montgomery, D.H. (1995). Response surface methodology. Wiley, New York.
Puri, A.B., & Bhattacharyya, B. (2003). An analysis and optimisation of the geometrical inaccuracy due to wire lag phenomenon in WEDM. International Journal Machine Tools & Manufacturing, 43(2), 151-159.
Puri, A.B., & Bhattacharyya, B. (2005). Modelling and analysis of white layer depth in a wire cut EDM process through response surface methodology. International Journal of Advance Manufacturing Technology, 25(3-4), 301-307.
Rebelo, J.C., Morao Dias, A., Kremer, D., & Lebrun, J.L. (1998). Influence of EDM pulse energy of on the surface integrity of martensitic steel. Journal of Materials Processing Technology, 84(1-3) , 90-96.
Sarkar, S., Sekh, M., Mitra, S., & Bhattacharyya, B. (2008). Modeling and optimization of wire electrical discharge machining of ?- TiAl in trim cutting operation. Journal of Materials Processing Technology, 205(1-3), 376-387.
Sarkar, S., Mitra, M., & Bhattacharyya, B. (2011). A novel method of determination of wire lag for enhanced profile accuracy in WEDM. Precision Engineering, 35(2), 339-347.
Sharman, A.R.C., Hughes, J.I., & Ridgway, K. (2004). Workpiece Surface Integrity and Tool Life Issues When Turning Inconel 718 TM Nickel Based Superalloy. Journal of Machine Science & Technology, 8(3), 399-414.
Sharma, N., Khanna, R., Gupta, R. D., & Sharma, R. (2013). Modeling and Multiresponse optimization on WEDM for HSLA by RSM. International Journal of Advance Manufacturing Technology, 67(9-12), 2269-2281.
Soo, S.L., Hood, R., Aspinwall, D.K., Voice, W.E., & Sage, C. (2011). Machinability and surface integrity of RR1000 nickel based super alloy. CIRP Annals- Manufacturing Technology, 60(1), 89–92.
Soo, S.L., Antar, M.T., Aspinwall, D.K., Sage, C., Cuttell, M., Perez, R., & Winn, A.J. (2013).The effect of wire electrical discharge machining on the fatigue life of Ti-6Al-2Sn-4Zr-6Mo aerospace alloy. Procedia CIRP, 6, 216-220.
Ulutan, D., & Ozel, T. (2011). Machining induced surface integrity in Titanium and Nickel Alloys-A review. International Journal of Machine Tools & Manufacture, 51(3), 250-280.
Wang, C.C., Chow, H.M., Yang, L.D., & Lu, C.T. (2009). Recast layer removal after electrical discharge machining via Taguchi analysis: a feasibility study. Journal of Materials Processing Technology, 209(8), 4134-4140.
Wei, X. (2002). Experimental study on the machining of a shaped hole Ni based super heat resistant alloy. Journal of Material Processing Technology, 129(1), 143-147.
Yang, R.T., Tzeng, C.J., Yang, Y.K., & Hsieh, M.H. (2012).Optimization of wire electrical discharge machining process parameters for cutting tungsten. International Journal of Advance Manufacturing Technology, 60(1-4), 135-147.
Bhuyan, B.K., & Yadava, V. (2014). Experimental Study of Travelling Wire Electrochemical Spark Machining of Borosilicate Glass. Materials and Manufacturing Processes, 29(3), 298-304.
Bobbili, R., Madhu, V., & Gogia, A.K. (2013).Effect of Wire-EDM Machining Parameters on Surface Roughness and Material Removal Rate of High Strength Armor Steel. Materials and Manufacturing Processes, 28(4), 364–368.
Cheng, X., Yang, X.H., Huang, Y.M., Zheng, G.M., & Li, L. (2014).Helical surface creation by wire electrical discharge machining for micro tools. Robotics and Computer-Integrated Manufacturing, 30(3), 287–294.
Choudhury, I.A., & El-Baradie, M.A. (1998). Machinability of nickel-base super alloys- a general review. Journal of Materials Processing Technology, 77(1-3), 278-284.
Cochran, G., & Cox, G.M. (1962). Experimental Design. Asia Publishing House, New Delhi.
Deringer, G., & Suich, R. (1980). Simultaneous optimization of several response variables. Journal of Quality Technology, 12(4), 214-219.
Ezugwu, E.O. (2005). Key improvements in the machining of difficult-to-cut aerospace alloys. International Journal of Machine Tools & Manufacture, 45(12-13), 1353-1367.
Guo, Y.B., Li, W., & Jawahir, I.S. (2009). Surface integrity characterization and prediction in machining of hardened and difficult-to-machine alloys-a state-of-art research review and analysis. Journal of Machine Science & Technology, 13(4), 437- 470.
Gupta, K., & Jain, N.K. (2014). Analysis and optimization of micro-geometry of miniature spur gears manufactured by wire electric discharge machining. Precision Engineering, 38(4), 728-737.
Han, F., Jiang, J., & Yu, D. (2007). Influence of machining parameters on surface roughness in finish cut of WEDM. International Journal of Advance Manufacturing Technology, 34(5-6), 538-546.
Hewidy, M.S., El-Taweel, T.A., & El-Safty, M.F. (2005). Modeling the machining parameters of wire electrical discharge machining of Inconel 601 using RSM. Journal of Materials Processing Technology, 169(2), 328–336.
Hood, R., Soo, S.L., Aspinwall, D.K., Andrews, P., & Sage, C. (2011). Twist drilling of Haynes 282 Superalloy, Procedia Engineering, 19, 150-155.
Huang, J.T., Liao, Y.S., & Hsue, W.J. (1999). Determination of finish- cutting operation and machining –parameters setting in wire electrical discharge machining. Journal of Materials Processing Technology, 87(1-3), 69-81.
Jangra, K., Grover, Chan FTS, & Aggarwal, A. (2011). A Digraph and matrix method to evaluate the machinability of tungsten carbide composite with wire EDM. International Journal of Advance Manufacturing Technology, 2(3), 959-974.
Jangra, K., Grover, S., & Aggarwal, A. (2011). Simultaneous optimization of material removal rate and surface roughness for WEDM of WC-Co composite using grey relational analysis along with Taguchi method. International Journal of Industrial Engineering Computations, 2(3), 479–490.
Jangra, K. (2012). Study of unmachined area in intricate machining after rough cut in WEDM. International Journal of Industrial Engineering Computations, 3(5), 887-892.
Jangra, K., & Grover, S. (2012). Modeling and experimental investigation of process parameters in WEDM of WC- 5.3% Co using response surface methodology. Mechanical Science, 3, 63-72.
Jangra, K.K., Kumar, V., Kumar, V. (2014). An experimental and comparative study on rough and trim cutting operation in WEDM of hard to machine materials. Procedia Materials Science, 5, 1603 – 1612.
Jangra, K.K. (2015). An experimental study for multi-pass cutting operation in wire electrical discharge machining of WC- 5.3% Co composite. International Journal of Advance Manufacturing Technology, 76, 971-982.
Khanna, R., & Singh, H. (2013) Performance analysis for D-3 material using response surface methodology on WEDM. International Journal of Machining and Machinability of Materials, 14, 45 – 65.
Klink, A., Guoa, Y.B., & Klocke, F. (2011).Surface integrity evolution of powder metallurgical tool steel by main cut and finishing trim cuts in wire-EDM. Procedia Engineering, 19, 178-183.
Kortabarria, A., Madariaga, A., Fernandez, E., Esnaola, J.A., & Arrazola, P.J. (2011).A comparative study of residual stress profiles on Inconel 718 induced by dry face turning, Procedia Engineering, 19, 228 – 234.
Krain, H.R., Sharman, A.R.C., & Ridgway, K. (2007). Optimisation of tool life and productivity when end milling Inconel 718 TM. Journal of Material Processing Technology, 189(1-3), 153-161.
Kumar, V., Jangra, K., & Kumar, V. (2012). Effect of WEDM parameters on machinability of Nimonic-90.Proceedings of the National Conference on Trends and Advances in Mechanical Engineering (TAME), YMCA University of Science and Technology, 511-516.
Lee, S.H., & Li, X.P. (2003).Study of the surface integrity of the machined workpiece in the EDM of tungsten carbide. Journal of Materials Processing Technology, 139(1-3), 315-321.
Li, L., Guo, Y.B., Wei, X. T., & Li, W. (2013). Surface integrity characteristics in wire-EDM of Inconel 718 at different discharge energy. Procedia CIRP, 6, 221 – 226.
Liao, Y.S., & Yu, Y.P. (2004). The energy aspect of material property in WEDM and its application. Journal of Materials Processing Technology, 149(1-3), 77–82.
Myers, R.H., & Montgomery, D.H. (1995). Response surface methodology. Wiley, New York.
Puri, A.B., & Bhattacharyya, B. (2003). An analysis and optimisation of the geometrical inaccuracy due to wire lag phenomenon in WEDM. International Journal Machine Tools & Manufacturing, 43(2), 151-159.
Puri, A.B., & Bhattacharyya, B. (2005). Modelling and analysis of white layer depth in a wire cut EDM process through response surface methodology. International Journal of Advance Manufacturing Technology, 25(3-4), 301-307.
Rebelo, J.C., Morao Dias, A., Kremer, D., & Lebrun, J.L. (1998). Influence of EDM pulse energy of on the surface integrity of martensitic steel. Journal of Materials Processing Technology, 84(1-3) , 90-96.
Sarkar, S., Sekh, M., Mitra, S., & Bhattacharyya, B. (2008). Modeling and optimization of wire electrical discharge machining of ?- TiAl in trim cutting operation. Journal of Materials Processing Technology, 205(1-3), 376-387.
Sarkar, S., Mitra, M., & Bhattacharyya, B. (2011). A novel method of determination of wire lag for enhanced profile accuracy in WEDM. Precision Engineering, 35(2), 339-347.
Sharman, A.R.C., Hughes, J.I., & Ridgway, K. (2004). Workpiece Surface Integrity and Tool Life Issues When Turning Inconel 718 TM Nickel Based Superalloy. Journal of Machine Science & Technology, 8(3), 399-414.
Sharma, N., Khanna, R., Gupta, R. D., & Sharma, R. (2013). Modeling and Multiresponse optimization on WEDM for HSLA by RSM. International Journal of Advance Manufacturing Technology, 67(9-12), 2269-2281.
Soo, S.L., Hood, R., Aspinwall, D.K., Voice, W.E., & Sage, C. (2011). Machinability and surface integrity of RR1000 nickel based super alloy. CIRP Annals- Manufacturing Technology, 60(1), 89–92.
Soo, S.L., Antar, M.T., Aspinwall, D.K., Sage, C., Cuttell, M., Perez, R., & Winn, A.J. (2013).The effect of wire electrical discharge machining on the fatigue life of Ti-6Al-2Sn-4Zr-6Mo aerospace alloy. Procedia CIRP, 6, 216-220.
Ulutan, D., & Ozel, T. (2011). Machining induced surface integrity in Titanium and Nickel Alloys-A review. International Journal of Machine Tools & Manufacture, 51(3), 250-280.
Wang, C.C., Chow, H.M., Yang, L.D., & Lu, C.T. (2009). Recast layer removal after electrical discharge machining via Taguchi analysis: a feasibility study. Journal of Materials Processing Technology, 209(8), 4134-4140.
Wei, X. (2002). Experimental study on the machining of a shaped hole Ni based super heat resistant alloy. Journal of Material Processing Technology, 129(1), 143-147.
Yang, R.T., Tzeng, C.J., Yang, Y.K., & Hsieh, M.H. (2012).Optimization of wire electrical discharge machining process parameters for cutting tungsten. International Journal of Advance Manufacturing Technology, 60(1-4), 135-147.