Effect of Welding Process Parameters on Toughness and Microstructure Characterization of IS 2062 Grade A Structural Steel Weldment
Authors
-
Jamia Millia Islamia, New Delhi-1100025 ,IN
Saadat Ali Rizvi
DOI:
https://doi.org/10.22486/iwj.v53i1.191277Keywords:
MIG, IS 2062, Microstructure, Toughness, Mode of Fracture, SEM, Shielding Gas.Abstract
In this research article, the effect of welding process parameters such as arc welding current, arc voltage, wire feed speed, and shielding gas flow rate on mechanical and metallurgical properties of IS 2062 Grade A steel bonded by MIG welding was investigated. In this experimental work, parent metal was welded by an ER70S-6 filler wire in the presence of a mixture of 75%Ar+25% CO gases for shielding purpose. The Toughness of weldment was 2 determined as mechanical properties. In metallurgical investigation of the weldment, Optical Microscopy (OM), Scanning Electron Microscopy (SEM) and Energy Dispersive Spectroscopy (EDS) were used. Fracture surfaces of notched toughness specimens were examined after toughness test. From experimental results, it was observed that on increasing the arc voltage, toughness value of weldment decreased and the grain size of microstructure of weldment varied throughout the weldment surface. Microstructure of weldment was also found influenced by the composition of shielding gases.Downloads
Published
Issue
Section
References
William HM (1991); Gas Metal Arc Welding Handbook, Goodheart-Willcox Company.
Nadkarni SV (1988); Modern welding technology, Oxford and IBP Publishing Co.(P) Ltd., New Delhi.
Rizvi SA and Ali W (2009); Advanced Welding Technology, SK Katariya and Sons (P) Ltd., New Delhi.
Srivastava S and Garg RK (2017); Process parameters optimization of gas metal arc welding on IS 2062 mild steel using response surface methodology, Journal of Manufacturing Process, 25, pp.296-305.
Chennaiah MB, Nanda Kumar P and Rao KP (2015); Effect of heat input and heat treatment on the mechanical properties of IS 2062-IS 103 Cr-1 steel weldments, International Journal of Advances in Material Science and Engineering, 4(3), pp.17-34.
Akslsen OM and Grong Ø (1992); Prediction of weld metal Charpy V notch toughness, Material Science and Engineering A, 159, pp.187-192.
Svensson Le and Gretoft B (1990); Microstructure and impact toughness of C-Mn weld metals, Welding Journal, Welding Research Supplement, pp.454- 461.
Magudeeswaran G, Balsubramanian V, Madhusudan Reddy G, Balasubrarnanian T (2008); Effect of welding process and consumables on tensile and impact properties of high strength quenched and tempered steel joints, Journal of Iron And Steel Research, International, 15(6), pp.87-94.
Abson DJ (1993); Microstructure and mechanical properties of gas shielded welding of C-Mn-Ni steel, Welding Research, pp.173-187.
Park BG, Crosky AG and Hellier AK (2008); Fracture toughness of microsphere Al2O3–Al particulate metal matrix composites, Composites: Part B, 39, pp.1270–1279.
ASTM (1983); Methods of Notched-Bar Impact Testing of Metallic Materials, E23-A3.1.Vol.03.01, Annual Book of ASTM Standards, Philadelphia.
Rizvi SA, Tewari SP and Ali W (2016); Application of Taguchi technique to optimize the process parameters of MIG wedging on IS 2062 steel, International Journal on Emerging Trends in Mechanical & Production Engineering, 2(2), pp.1-11.
Ragunathan S, Balasubramanian V, Malarvizhi S and Rao AG (2015); Effect of welding process on mechanical and microstructural characteristics of high strength low allow navel grade steel joint, Defense Technology, 11(3), pp.308-317.
Suhail M, Faizan M and Bharti PK (2014); Effect of welding speed, current and voltage on mechanical properties of underwater welded mild steel specimen (C, Mn, Si) with insulated electrode E6013, MIT International Journal of Mechanical Engineering, 4(2), pp.120-124.
Zhang H, Zhou M and Hu HJ (2001); Impact strength measurement of spot welds, Proc. Instn. Mech. Engrs, Part-B, 215, pp.403-414.
Li HL, Liu D, Yan YT, Guo N and Feng JC (2016); Microstructure characteristics and mechanical properties of underwater wet flux-cored wire welded 316L stainless steel joint, Journal of Materials Processing Technology, 238, pp.423-430.
