https://orcid.org/0000-0002-6581-4131
References
- Karadeniz E, Ozsarac U, Yildiz C. The effect of process parameters on penetration in gas metal arc welding process. Mater Des. 2007;28(2):649–656.
- Suban M, Tusek J. Methods for the determination of arc stability. J Mater Process Technol. 2003;143-144:430–437.
- Rathinasuriyan C, Kumar VSS, V S. Mechanical and metallurgical properties of GTAW, GMAW and FSW lap joints on AA6061-T6 Alloy. Adv Mater Process Technol. 2021;1–17. DOI:10.1080/2374068x.2021.1946322
- Misra RK, Porwal R, Saxena KK, et al. Effect of post weld heat treatment on mechanical properties of MIG welded mild steel. Adv Mater Process Technol. 2021;1–15. DOI:10.1080/2374068x.2021.1934644
- Gunaraj V, Murugan N. Prediction and comparison of the area of the heat-affected zone for the bead-on-plate and bead-on-joint in submerged arc welding of pipes. Journal of Materials Processing Technology. 1999;95(1–3):246–261.
- Murugan N, Parmar RS, Sud SK. Effect of submerged arc process variables on dilution and bead geometry in single wire surfacing. Journal of Material Processing and Technology. 1999;371:767–780.
- Murugan N, Parmar RS. Effect of MIG process parameters on the geometry of the bead in the automatic surfacing of stainless steel. Journal of Material Processing and Technology. 1994;41(4):381–398.
- Ribeiro R, Romão EL, Luz E, et al. Optimization of the resistance spot welding process of 22MnB5-galvannealed steel using response surface methodology and global criterion method based on principal components analysis. Metals. 2020;10(10):1338.
- Koleva E. Electron beam weld parameters and thermal efficiency improvement. Vacuum. 2005;77(4):413–421.
- Liu G, Gao X, Peng C, et al. Optimization of laser welding of DP780 to Al5052 joints for weld width and lap-shear force using response surface methodology. Opt Laser Technol. 2020;126:1–8. 18.
- Tyagi L, Butola R, Kem L, et al. Comparative analysis of response surface methodology and artificial neural network on the wear properties of surface Composite fabricated by friction Stir processing. Journal of Bio- and Tribo-Corrosion. 2021;7(2). DOI: 10.1007/s40735-020-00469-1.
- Meena SL, Butola R, Murtaza Q, et al. Metallurgical Investigations of Microstructure and Micro hardness across the various zones in Synergic MIG Welding of Stainless steel. Mater Today Proc. 2017;4(8):8240–8249.
- Butola R, Singari RM, Murtaza Q, et al. Comparison of response surface methodology with artificial neural network for prediction of the tensile properties of friction stir-processed surface composites. Proc Inst Mech Eng Part E. 2022;236(1):126–137.
- Srivastava S, Garg R. Process parameter optimization of gas metal arc welding on IS: 2062 mild steel using response surface methodology. J Manuf Processes. 2017;25:296–305.
- Wagner JR, Mount EM, Giles HF. 25 - design of experiments. Extrusion (Second Edition) ed. Norwich, NY: William Andrew Publishing; 2014. p. 291–308.
- Butola R, Meena SL, Kumar J. Effect of welding parameters on microhardness of synergic MIG welding of 304L austenitic steel. Int J Mech Eng Technol. 2013;4(3):337–343.
- Shahi AS, Pandey S. Modelling of the effects of welding conditions on dilution of stainless steel claddings produced by gas metal Arc welding procedures. J Mater Process Technol. 2008;196(1–3):339–344.
- Parappagoudar MB, Pratihar DK, Datta GL. Non-linear modelling using central composite design to predict green sand mould properties. Proc Inst Mech Eng Part B. 2007;221(5):881–895.