Evaluation of induced residual stresses on AISI 1020 low carbon steel plate from experimental and FEM approach during TIG welding process

Authors

  • I. B. Owunna Department of Mechanical Engineering, University of Benin, PMB 1154, Edo State, Nigeria Phone: +2349024773812
  • A. E. Ikpe Department of Mechanical Engineering, University of Benin, PMB 1154, Edo State, Nigeria Phone: +2349024773812

DOI:

https://doi.org/10.15282/jmes.13.1.2019.06.0376

Keywords:

Residual stress, failure, welded joint, welding temperature, flat plate

Abstract

Induced residual stresses on AISI 1020 low carbon steel plate during Tungsten Inert Gas (TIG) welding process was evaluated in this study using experimental and Finite Element Method (FEM). The temperature range measured from the welding experimentation was 251°C-423°C, while the temperature range measured from the FEM was 230°C-563°C; whereas, the residual stress range measured from the welding experimentation was 144MPa-402Mpa, while the residual range measured from the FEM was 233-477MPa respectively. Comparing the temperature and stress results obtained from both methods, it was observed that the range of temperature and residual stresses measured were not exactly the same due to the principles at which both methods operate but disparities between the methods were not outrageous. However, these values can be fed back to optimization tools to obtain optimal parameters for best practices.  Results of the induced stress distribution was created from a static study where the thermal results were used as loading conditions and it was observed that the temperature increased as the von-Mises stress increased, indicating that induced stresses in welded component may hamper the longevity of such component in service condition. Hence, post-weld heat treatment is imperative in order to stress relieve metals after welding operation and improve their service life.

References

Wor LC, Rahman MM, Stress Behaviour of Tailor-Welded Blanks for Dissimilar Metals Using Finite Element Method. International Journal of Automotive and Mechanical Engineering 2015;11:2541-2554.

Yaakob KI, Ishak M, Idris SR, The Effect of Pulse Welding Parameters on Weld Geometry of Boron Steel Using Low Power Fibre Laser. Journal of Mechanical Engineering and Sciences 2017;11:2895-2905.

Razak NA, Shing SN, Investigation of Effects of MIG Welding Corrosion Behaviour of AISI 1010 Carbon Steel. Journal of Mechanical Engineering and Sciences 2014;7:1168-1178.

Nuraini AA, Zainal AS, Hanim MA, The effects of Welding Parameters on Butt Joints Using Robotic Gas Metal Arc Welding. Journal of Mechanical Engineering and Sciences 2014;6:988-994.

Ghazali FA, Manurung YH, Mohamed MA, Alias SK, Abdulla S, Effect of Process Parameters on the Mechanical Properties and Failure Behaviour of Spot Welded Low Carbon Steel. Journal of Mechanical Engineering and Sciences 2015;8:1489-1497.

Ikpe AE, Owunna I, Ememobong, I, Effects of Arc Voltage and Welding Current on the Arc Length of Tungsten Inert Gas Welding (TIG). International Journal of Engineering Technologies 2017;3:213-221.

Ravichandran M, Sait AN, Vignesh U, Investigation on TIG Welding Parameters of 2205 Duplex Stainless Steel. International Journal of Automotive and Mechanical Engineering 2017;14:4518-4530.

Deng D, Luo Y, Serizawa H, Shibahara M, Murakawa, H, Numerical Simulation of Residual Stresses and Deformation Considering Phase Transformation Effect. Transactions of Joining and Welding Research Institute 2003;32:325–333.

Tsai C, Kim D, Understanding residual stresses and distortion in welds: an overview. Processes and mechanisms of welding residual stresses and distortion. In: Feng Z, Processes and mechanisms of welding residual stresses and distortion. CRC Press, Florida. 2005;3–6.

Radaj D, Welding residual stresses and distortion: calculation and measurement 2nd edn. Verlag für Schweissen und Verwandte Verfahren, DVS-Verlag. 2003;118–200.

Zain-ul-Abdein M, Nelias D, Jullien J, Deloison D, Prediction of Laser Beam Welding-Induced Distortions and Residual Stresses by Numerical Simulation for Aeronautic Application. Journal of Materials Processing Technology 2009;209:2907–2917.

Yaghi A, Becker A, State of the Art Review-Weld Simulation Using Finite Element Method. University of Nottingham, UK, Report No: FENET-UNOTT-DLE-08. 2004; 1-27.

Wei L, Junjie M, Fanrong K, Shuang L, Radovan K, Numerical Modelling and Experimental Verification of Residual Stress in Autogenous Laser Welding of High-Strength Steel. Lasers in Manufacturing and Materials Processing 2015;2:24–42.

Qian Z, Chumbley S, Johnson E, The Effect of Specimen Dimension on Residual Stress Relaxation of Carburized and Quenched Steels. Materials Science and Engineering: A 2011;529:246–252.

Mohamed SA, Abdulla S, Arifin A, Arifin AK, Padzi MM, Characterization of the Biaxial Fatigue Behaviour on Medium Carbon Steel Using the Strain-life Approach. International Journal of Automotive and Mechanical Engineering 2016;13: 3262-3277.

Taylor GA, Hughes M, Strusevich N, Pericleous K, Finite Volume Methods Applied to the Computational Modelling of Welding Phenomena. Applied Mathematical Modelling 2002;26:309-320.

Minh PS, Phu TV, Study on the Structure Deformation in the Process of Gas Metal Arc Welding (GMAW). American Journal of Mechanical Engineering 2014;2:120-124.

Goldak JA, Akhlaghi M, Computational Welding Mechanics. Springer, New York, USA. 2005; 9780387232881.

Goldak J, Chakravarti A, Bibby M, A New Finite Element Model for Welding Heat Source. International Journal Metallurgical and Materials Transactions B 1984;15:299-305.

Paradowska AM, Zhao X, Stress Relieving and its Effect on Life of Welded Tubular Joints. Engineering Failure Analysis 2010;17:320-327.

Kang HT, Lee Y, Sun XJ, Effects of Residual Stress and Heat Treatments on Fatigue Strength of Weldments. Material Science and Engineering: A 2008;497:37-43.

Hatamleh O, Rivero I, Lyons, J, Evaluation of Surface Residual Stresses in Friction Stir Welds due to Laser and Shot Peening. Journal of Materials Engineering and Performance 2007;16:549–553.

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Published

2019-03-28

How to Cite

[1]
I. B. Owunna and A. E. Ikpe, “Evaluation of induced residual stresses on AISI 1020 low carbon steel plate from experimental and FEM approach during TIG welding process”, J. Mech. Eng. Sci., vol. 13, no. 1, pp. 4415–4433, Mar. 2019.

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