OPTIMIZATION OF FCA AND MIG WELDING PARAMETERS FOR AISI-1045 STEEL

Authors

  • C.C. Irechukwu Department of Mechanical Engineering, Federal University of Technology, Minna-Nigeria
  • S. A. Lawal Department of Mechanical Engineering, Federal University of Technology, Minna-Nigeria
  • I. O. Sadiq Department of Mechanical Engineering, Federal University of Technology, Minna-Nigeria
  • A.A. Abdullahi Department of Mechanical Engineering, Federal University of Technology, Minna-Nigeria
  • J. Abutu Department of Mechanical Engineering, Taraba State University, Jalingo

DOI:

https://doi.org/10.4314/njt.2025.5580

Keywords:

Welding; , FCAW, , MIGW, , grey relational analysis; , Taguchi; , welding parameters

Abstract

Welding is a vital industrial process for joining metals and thermoplastics, with Metal Inert Gas (MIG) and Flux Cored Arc (FCA) welding widely used due to their versatility and effectiveness. This study optimized FCA and MIG welding parameters for AISI 1045 alloy steel using Response Surface Methodology (RSM) via Central Composite Design (CCD) L20(5)3 in Minitab 20. The parent material and weldments were characterized through standard testing methods. X-ray fluorescence (XRF) analysis confirmed the material as galvanized medium-carbon steel containing 0.376% carbon and 22–25% iron, while revealing a crystalline structure with features indicating crystal size and possible defects. Mechanical testing showed UTS values for welds were generally lower than the base metal, high joint efficiencies confirmed good bonding. Also, optimal conditions for hardness (FCAW: 4.6 kgm/s, 73.2 A, 28 mm; MIG: 8 kgm/s, 73.2 A, 24.6 mm), UTS (FCAW: 10 kgm/s, 73.2 A, 26 mm; MIG: 8 kgm/s, 73.2 A, 24.6 mm), and impact strength (MIG: 6 kgm/s, 106.8 A, 26 mm), with gas flow rate as the dominant factor and refined microstructures confirming superior weld quality and bonding. Both welds were free from porosity and cracks, underscoring the importance of parameter optimization for superior weld quality and mechanical performance.

References

REFERENCES

[1] Rahadian, N. “Advancements in welding technology: A comprehensive review of techniques, materials, and applications,” Journal PEP Bandung, 2 (1), p. 62–110, 2025.

[2] Khan, F. Hossain, N. Mim, J. J. Rahman, S. M. Iqbal, M. J. Billah, M. and Chowdhury, M. A. “Advances of composite materials in automobile applications – A review,” Journal of Engineering Research, (online first), p. 1001-1023, 2024, doi: 10.1016/j.jer.2024.02.017.

[3] Kearns, W. H. Welding Handbook. Resistance of solid-state welding and other joining processes, 7th ed., Vol. 3, American Welding Society, 2020.

[4] Messler, R. W. Principle of welding processes, Wiley–VCH Verlag GmbH & Co. KGaA, Weinheim, 2023.

[5] Vats, V. Melton, G. Islam, M. and Krishnan, V. V. “Investigation into Cr (VI) generation in metal inert gas (MIG), metal active gas (MAG), and flux cored arc welding (FCAW) by varying the oxidation potential of the shielding gas,” Welding in the World, 67 (10), p. 2301–2313, 2023.

[6] Sharma, S. and Singh, L. “A review on the flux cored arc welding through process parameter,” International Journal of Scientific Research in Mechanical and Materials Engineering, 47, p. 777–780, 2023.

[7] Chaturvedi, M. and Vendan, S. A. Advanced welding techniques, Springer, Berlin, Germany, 2022.

[8] Vijayavel, P. Mahesh, G. and Venkatswarmy, M. “Optimisation of MIG welding parameters for improving strength of welding joint in AISI 10405 steel,” International Journal of Mechanical Engineering, 1 (2), p. 1–8, 2018.

[9] Ajit, H. Ashwari, D. and Satpal, S. “Optimisation of MIG welding process parameters to predict maximum field strength in AISI 1040,” Industrial Journal of Mechanical Engineering, 1 (3), p. 203-213, 2012.

[10] Raja, S. K. Balaji, N. Balasubrananian, K. and Rajendran, C. “Effect of MIG welding process parameters on microstructure and tensile behaviour of Hastelloy C276 using response surface methodology,” International Journal of Mechanical Engineering, 1, p. 1–7, 2019, doi: 10.1088/2053-1591/ab093a.

[11] Doniawi, A. Hassani, G. and Ranjbanj, (initials not given). “Prediction and optimisation of mechanical properties of St52 in gas metal arc weld using response surface methodology and ANOVA,” International Journal of Engineering, 29 (9), p. 1–7, 2016.

[12] Izzatul, A. I. Ashwani, D. and Satpal, S. “Optimisation of MIG welding process parameters to predict maximum yield strength in AISI 1040,” International Journal of Mechanical Engineering and Robotics Research, 1 (3), p. 1–11, 2012.

[13] Kashif, N. and Anwar, K. S. “Response surface methodology for FCAW for best weld condition on desirability function,” Journal of Material Sciences and Engineering, 8 (2), p. 1–10, 2020.

[14] Rayindra, K. M. and Rajesh, K. P. “Optimisation of metal inert gas welding process during joining of structural steel,” E3S Web of Conferences, 184, p. 01028, 2020, doi: 10.1051/e3sconf/202018401028.

[15] Madavi, K. R. Jogi, B. F. and Lohar, G. S. “Metal inert gas (MIG) welding process: A study of effect of welding parameters,” Materials Today: Proceedings, 51, p. 690–696, 2022.

[16] Smart, S. C. “Effect of process variables on weld metal hydrogen-assisted cold cracking in multipass welds of high strength steels,” Ph.D. dissertation, University of Leicester, 2024.

[17] Abutu, J. Lawal, S. A. Ndaliman, M. B. Lafia-Araga, R. A. Adedipe, O. and Choudhury, I. A. “Production and characterization of brake pad developed from coconut shell reinforcement material using central composite design,” SN Applied Sciences, 1 (18), p. 1–16, 2019.

[18] Irechukwu, C. C. Khan, R. H. Abutu, J. Lawal, S. A. and Namessan, N. O. “Effect of tungsten inert gas welding parameters on the performance of AISI 304 alloy steel using multi-response optimisation technique,” Welding International, 35 (1–3), p. 45–58, 2021.

[19] Benyounis, K. Y. and Olabi, A. G. “Optimisation of different welding processes using statistical and numerical approaches – A reference guide,” Advances in Engineering Software, 39 (6), p. 483–496, 2008.

[20] Adedipe, O. Gambo, A. B. Abutu, J. Olugboji, O. A. Agboola, J. B. Obanimomo, K. T. and Abdulrahman, A. S. “An evaluation of mechanical properties and estimation of environmental reduction factors in welded API X70 steel pipeline in natural seawater,” Welding International, 37 (5), p. 269–281, 2023.

[21] Singh, S. Samir, S. Kumar, K. and Thapa, S. “Effect of heat treatment processes on the mechanical properties of AISI 1045 steel,” Materials Today: Proceedings, 45, p. 5097–5101, 2021.

[22] Hossain, M. S. Shaikh, M. A. A. Rahaman, M. S. and Ahmed, S. “Modification of the crystallographic parameters in a biomaterial employing a series of gamma radiation doses,” Molecular Systems Design & Engineering, 7 (10), p. 1239–1248, 2022.

[23] Salem, K. S. Kasera, N. K. Rahman, M. A. Jameel, H. Habibi, Y. Eichhorn, S. J. … and Lucia, L. A. “Comparison and assessment of methods for cellulose crystallinity determination,” Chemical Society Reviews, 52 (18), p. 6417–6446, 2023.

[24] Igwe, N. C. Akhrif, I. and El Jai, M. “On the machinability of additively manufactured AlSi10Mg: factorial analysis and multi-objective optimization,” International Journal on Interactive Design and Manufacturing (IJIDeM), p. 1–42, 2025.

[25] Igwe, N. C. Igwe, A. C. Ononiwu, N. H. Ozoegwu, C. G. Akhrif, I. and El Jai, M. “Taguchi-grey relational optimization of surface roughness and tool wear in turning of rice husk ash reinforced aluminum,” Moroccan Journal of Chemistry, 13 (3), p. JChem–??, 2025.

[26] Igwe, N. C. Akhrif, I. El Jai, M. and El Fahime, B. “An experimental investigation of the influence of SLM input factors on the as-built AlSi10Mg surface quality,” The International Journal of Advanced Manufacturing Technology, 136 (2), p. 619–674, 2025.

[27] Igwe, N. C. Salim, R. Ech-chihbi, E. Akhrif, I. El Jai, M. and Hammouti, B. “The influence of laser powder bed fusion process parameters on the corrosion behavior of AlSi10Mg alloy in NaCl solution,” The International Journal of Advanced Manufacturing Technology, p. 1–10, 2025.

[28] Van, A. L. Truong-An, N. Trung-Thanh, N. and Dang, X. B. “Multi-performance optimization of gas metal arc welding operation in terms of energy saving and quality criteria,” Journal of Adhesion Science and Technology, 39 (1), p. 76–105, 2025.

[29] Lawong, A. Nampromma, S. Sudsuansee, T. and Sergsiri, S. “Multi-response optimization of robotic welding parameters using a Taguchi-based random forest model for dissimilar joining materials,” Engineering, Technology & Applied Science Research, 15 (5), p. 27237–27243, 2025.

[30] Jawad, M. Jahanzaib, M. Ali, M. A. Farooq, M. U. Mufti, N. A. Pruncu, C. I. Salman, H. and Wasim, A. “Revealing the microstructure and mechanical attributes of pre-heated conditions for gas tungsten arc welded AISI 1045 steel joints,” International Journal of Pressure Vessels and Piping, 192, p. 104440, 2021.

[31] Marimuthu, P. K. Sri Kurumurthy, G. Thenarasu, M. and Venkata Roshan, M. “Minimizing residual stresses in AISI 1045 steel through optimization of cutting parameters: A particle swarm optimization approach,” Proceedings of the Institution of Mechanical Engineers, Part E: Journal of Process Mechanical Engineering, p. 09544089251318779, 2024.

[32] Şeker, A. Değirmencioğlu, F. and Karakuş, M. “Investigation of the effects of shielding gas flow rate on weld penetration in MIG welding,” Journal of Materials and Manufacturing (J. Mater. Manuf.), 2 (2), p. 28–37, 2023.

[33] Abd Rahman, M. N. Zulkipli, N. H. Kasim, M. S. Jamli, M. R. and Budi, E. “Impact of argon gas shielding flow rate on the hardness of weld joint,” Journal of Advanced Manufacturing Technology, 16 (1), p. 1–10, 2022.

[34] Li, T. Zhang, Y. Gao, L. and Zhang, Y. “Optimization of FCAW parameters for ferrite content in 2205 DSS welds based on the Taguchi design method,” Advances in Materials Science and Engineering, 2018 (1), p. 7950607, 2018.

[35] Liang, Z. Li, H. Wang, Q. Sun, X. Gao, X. Yuan, S., Yang, Z and Zhang, F. “Enhancing the resistance to hydrogen embrittlement in bainitic steel via grain refinement, dislocation density reduction, and retained austenite stability improvement,” Journal of Materials Science & Technology, 247, p. 214–225, 2026.

[36] Shuvo, M. M. “Improving sustainability of sand-casting processes via novel 3D mold designs,” Ph.D. dissertation, Pennsylvania State University, 2023

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Published

2025-12-19

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2025: NIJOTECH DECEMBER 2025 EARLY VIEW

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Chemical, Industrial, Materials, Mechanical, Metallurgical, Petroleum & Production Engineering

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How to Cite

OPTIMIZATION OF FCA AND MIG WELDING PARAMETERS FOR AISI-1045 STEEL. (2025). Nigerian Journal of Technology, 44. https://doi.org/10.4314/njt.2025.5580
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