Evaluation of welding-induced residual stress and distortion in A-TIG welding of duplex stainless steel

Authors

  • A. Siyavoshi Department of Materials Engineering, Science and Research Branch, Islamic Azad University, 1477893855, Tehran, Iran
  • S. Shakhesi Department of Materials Engineering, Science and Research Branch, Islamic Azad University, 1477893855, Tehran, Iran
  • M. Reza Afshar Department of Materials Engineering, Science and Research Branch, Islamic Azad University, 1477893855, Tehran, Iran
  • Marzieh Hashemzadeh Centre for Marine Technology and Ocean Engineering (CENTEC), Instituto Superior Técnico, Universidade de Lisboa, 1049001, Portugal
  • M. Noghabi Department of Mechanical Engineering, Amirkabir University of Technology, 1591634311, Tehran, Iran

DOI:

https://doi.org/10.15282/jmes.17.1.2023.3.0737

Keywords:

Welding, Residual stress, Distortion, Welding simulation

Abstract

Applying non-uniform heat in welding causes residual stress and distortion, which affects the life of components. In the present study, the residual stress and distortion of Duplex 2205 stainless steel in A-TIG welding were investigated numerically and experimentally. The optimal welding parameters for highest penetration depth in welded samples were obtained experimentally. Uncoupled thermal-mechanical analysis using ABAQUS 2017 software has been done. Goldak's parameters were measured by empirical tests. The results include simulation diagrams of four samples consisting of the optimal sample without flux powder and three samples with the highest penetration depth. The simulation results show that the sample without flux has a higher maximum temperature and lower welding-induced distortions. The efficiency used in this research changes using and not using powder; it is concluded that, in similar conditions in A-TIG welding, fewer values of parameters are needed to achieve the appropriate result comparing conventional TIG. The efficiency of workpieces with flux should be considered about 20% lower to have similar results to the conventional TIG. The numerical modeling results showed a good agreement with experimental data both for temperature distribution and welding-induced residual stress and distortion. The distortion in the pieces with conventional TIG welding has increased to 11% at the farthest point from the welding line. The error obtained from comparing the results in residual stress is between 12 and 34%.

References

E. Ahmadi, A. R. Ebrahimi, and R. Azari Khosroshahi, "Welding of 304L stainless steel with activated Tungsten inert gas process (A-TIG)," (in english), International Journal of Iron & Steel Society of Iran,vol. 10, no. 1, pp. 27-33, 2013.

S. Mohan Kumar and N. S. Shanmugam, "Finite element simulation for tensile and impact test of activated TIG welding of AISI 321 austenitic stainless steel," Proceedings of the Institution of Mechanical Engineers, PartL,vol. 233, no. 11, pp. 2323-2334, 2019.

L. Natrayan, R. Anand, and S. Santhosh Kumar, "Optimization of process parameters in TIG welding of AISI 4140 stainless steel using Taguchi technique," Materials Today: Proceedings, vol. 37, pp. 1550-1553, 2021.

A. N. Chaudhari, K. Dixit, G. S. Bhatia, B. Singh, P. Singhal, and K. K. Saxena, "Welding behaviour of duplex stainless Steel AISI 2205: AReview," Materials Today: Proceedings, vol.18, pp. 2731-2737, 2019.

T. S. Chern, K. H. Tseng, and H. L. Tsai, "Study of the characteristics of duplex stainless-steelactivated tungsten inert gas welds," Materials & Design, vol. 32, no. 1, pp. 255-263, 2011.

G. Venkatesan, J. George, M. Sowmyasri, and V. Muthupandi, "Effect of ternary fluxes on depth of penetration in A-TIG welding of AISI 409 ferritic stainless steel," Procedia Materials Science, vol. 5, pp. 2402-2410, 2014.

K. H. Tseng, "Development and application of oxide-based flux powder for tungsten inert gas welding of austenitic stainless steels," Powder Technology, vol. 233, pp. 72-79, 2013.

A. K. Unni and M. Vasudevan, "Numerical modelling of fluid flow and weld penetration in activated TIG welding," Materials Today: Proceedings,vol. 27, pp. 2768-2773, 2020.

S. Tathgir, D. W. Rathod, and A. Batish, "A-TIG welding process for enhanced-penetration in Duplex stainless-steel: effect of activated fluxes," Materials and Manufacturing Processes,vol. 34, no. 15, pp. 1659-1670, 2019.

A. K. Unni, and V. Muthukumaranv, "Numerical simulation of the influence of oxygen content on the weld pool depth during activated TIG welding," The International Journal of AdvancedManufacturing Technology,vol.112 no. 1 ,pp. 467-489, 2021.

A. R. Kohandehghan, S. Serajzadeh, and A. H. Kokabi, "A study on residual stresses in gas tungsten arc welding of AA5251," Materials and Manufacturing Processes, vol. 25, no. 11, pp. 1242-1250, 2010.

K. C. Ganeshet al., "Modeling, prediction and validation of thermal cycles, residual stresses and distortion in type 316 LN stainless steel weld joint made by TIG welding process," Procedia Engineering, vol. 86, pp. 767-774, 2014.

D. Deng, "FEM prediction of welding residual stress and distortion in carbon steel considering phase transformation effects," Materials & Design,vol. 30, no. 2, pp. 359-366, 2009.

A. S. Ahmad, Y. Wu, H. Gong, and L. Nie, "Finite element prediction of residual stress and deformation induced by double-pass TIG welding of Al 2219 plate," Materials, vol. 12, no. 14, p. 2251, 2019.

D. Deng and H. Murakawa, "Prediction of welding distortion and residual stress in a thin plate butt-welded joint," Computational Materials Science,vol. 43, no. 2, pp. 353-365, 2008.

P. Colegroveet al., "Welding process impact on residual stress and distortion," Science and Technology of Welding and Joining, vol. 14, no. 8, pp. 717-725, 2009.

P. Vasantharaja, V. Maduarimuthu, M. Vasudevan, and P. Palanichamy, "Assessment of residual stresses and distortion in stainless steel weld joints," Materials and Manufacturing Processes, vol. 27, no. 12, pp. 1376-1381, 2012.

P. Vasantharaja, M. Vasudevan, and P. Palanichamy,"Effect of welding processes on the residual stress and distortion in type 316LN stainless steel weld joints,” Journalof Manufacturing Processes, vol. 19, pp. 187-193, 2015.

E. D. Derakhshan, N. Yazdian, B. Craft, S. Smith, and R. Kovacevic, "Numerical simulation and experimental validation of residual stress and welding distortion induced by laser-based welding processes of thin structural steel plates in butt joint configuration," Optics & Laser Technology, vol. 104, pp. 170-182, 2018.

V. García-García, I. Mejía, F. Reyes-Calderón, J. A. Benito, and J. M. Cabrera, "FE thermo-mechanical simulation of welding residual stresses and distortion in Ti-containing TWIP steel through GTAW process," Journal of Manufacturing Processes, vol. 59, pp. 801-815, 2020.

J. Chenet al., "An experimental and numerical analysis of residual stresses in a TIG weldment of a single crystal nickel-base superalloy," Journal of Manufacturing Processes, vol. 53, pp. 190-200, 2020.

J. Sun, J. Klassen, T. Nitschke-Pagel, and K. Dilger, "Effects of heat source geometric parameters and arc efficiency on welding temperature field, residual stress, and distortion in thin-plate full-penetration welds," The International Journal of AdvancedManufacturing Technology,vol. 99, no.1, pp. 497-515, 2018.

M. Zubairuddin, S. K. Albert, S. Mahadevan, M. Vasudevan, V. Chaudhari, and V. K. Suri, "Experimental and finite element analysis of residual stress and distortion in GTA welding of modified9Cr-1Mo steel," Journal of Mechanical Science and Technology,vol. 28, no. 12, pp. 5095-5105, 2014.

M. Farhang, O, Sam-Daliri, M. R. Farahani, and A. Vatani, "Effect of friction stir welding parameters on the residual stress distribution of Al-2024-T6 alloy," Journal of Mechanical Engineering and Sciences, vol. 15, no. 1, pp. 7684-7694, 2021.

S. Gao, S. Geng, P. Jiang, G. Mi, C. Han, and L. Ren, "Numerical analysis of the deformation behavior of 2205 duplex stainless steel TIG weld joint based onthe microstructure and micro-mechanical properties," Materials Science and Engineering A, vol. 815, p. 141303, 2021.

M. Hashemzadeh, Y. Garbatov, and C. G. Soares, "Analytically based equations for distortion and residual stress estimations of thin butt-welded plates," Engineering Structures, vol. 137, pp. 115-124, 2017.

B. Varbai and K. Májlinger, "Physical and theoretical modeling of the nitrogen content of duplex stainless-steelweld metal: Shielding gas composition and heat input effects," Metals, vol. 9, no. 7, p. 762, 2019.

M. Jurica, Z. Kožuh, I. Garašić, and M. Bušić, "Optimization of the A-TIG welding for stainless steels," IOP Conference Series: Materials Science and Engineering, vol. 329, 2018.

Y. Chen, B. Yang, Y. Zhou, Y. Wu, and H. Zhu, "Evaluation of pitting corrosion in duplex stainless steel Fe20Cr9Ni for nuclear power application," Acta Materialia, vol. 197, pp. 172-183, 2020.

A. Mahajan, S. S. Sidhu, and S. Devgan, "Examination of hemocompatibility and corrosion resistance of electrical discharge-treated duplex stainless steel (DSS-2205) for biomedical applications," Applied Physics A, vol. 126, no. 9, pp. 1-11, 2020.

V. D. Kalyankar and G. P. Chudasama, "Influence of electrode tip diameter on metallurgical andmechanical aspects of spot welded duplex stainless steel," High Temperature Materials and Processes, vol. 39, no. 1, pp. 317-327, 2020.

A. K. Maurya, C. Pandey, and R. Chhibber, "Dissimilar welding of duplex stainless steel with Ni alloys: A review," International Journal of Pressure Vessels and Piping, vol. 192, p. 104439, 2021.

S. Madhankumar, K. Manonmani, V. Karthickeyan, and N. Balaji, "Optimization of ultimate tensile strength of welded Inconel 625 and duplex 2205," Journal of Mechanical Engineering and Sciences, vol. 15, no. 1, pp. 7715-7728, 2021.

G. Magudeeswaran, S. R. Nair, L. Sundar, and N. Harikannan, "Optimization ofprocess parameters of the activated tungsten inert gas welding for aspect ratio of UNS S32205 duplex stainless-steelwelds,"Defence Technology, vol. 10, no. 3, pp. 251-260, 2014.

A. I. Mourad, A. Khourshid, and T. Sharef, "Gas tungsten arc and laserbeam welding processes effects on duplex stainless steel 2205 properties," Materials Science and Engineering A, vol. 549, pp. 105-113, 2012.

N. N. Korra, M. Vasudevan, and K. R. Balasubramanian, "Multi-objective optimization of activated tungsten inert gas welding of duplex stainless-steelusing response surface methodology,"The International Journal of Advanced Manufacturing Technology,vol. 77, no. 1, pp. 67-81, 2015.

K. N. Naik, K. Balasubramanian, and M. Vasudevan, "Finite element simulationof A-TIG welding of duplex stainless steel 2205 using SYSWELD,"Applied Mechanics and Materials, vol. 592, pp. 374-379, 2014.

B. Brickstad and B. L. Josefson, "A parametric study of residual stresses in multi-pass butt-welded stainless steel pipes," International Journal of Pressure Vessels and Piping, vol. 75, no. 1, pp. 11-25, 1998.

C. R. Xavier, H. G. Delgado, and J. A. d. Castro, "An experimental and numerical approach for the welding effects on the duplex stainless-steelmicrostructure," Materials Research, vol. 18, pp. 489-502, 2015.

Ø. Grong, Metallurgical Modelling of Welding. Institute of Materials, 1997.

M. Slováček, V. Diviš, L. Junek, V. Ochodek, "Numerical simulation of the welding process—distortion and residual stress prediction, heat source model determination," Welding in the World,vol. 49, no. 11, pp. 15-29, 2005.

K. D. Ramkumaret al., "Investigations on structure–property relationships of activated flux TIG weldments of super-duplex/austenitic stainless steels," Materials Science and Engineering A, vol. 638, pp. 60-68, 2015.

M. Eftekhari, M. Ahmadi Najaf Abadi, and M. Farahani, "Evaluation of longitudinal residual stress variations along the thickness of welded joint of 5086 aluminum alloy," Journal of Solid and Fluid Mechanics, vol. 7, no. 3, pp. 1-16, 2017.

C. Liu, Y. Luo, M. Yang, and Q. Fu, "Three-dimensional finite element simulation of welding residual stress in RPV with two J-groove welds," Welding in the World,vol. 61, no. 1, pp. 151-160, 2017.

F. A. Kandil, J. D. Lord, A. T. Fry, and P. V. Grant, "A review of residual stress measurement methods-a guide to technique selection," NPL Report MATC(A)O4, National Physical Laboratory, Middlesex, UK, 2001.

Downloads

Published

2023-03-23

How to Cite

[1]
A. Siyavoshi, S. Shakhesi, M. R. Afshar, M. Hashemzadeh, and M. Noghabi, “Evaluation of welding-induced residual stress and distortion in A-TIG welding of duplex stainless steel”, J. Mech. Eng. Sci., pp. 9324–9337, Mar. 2023.

Issue

Section

Article

Similar Articles

<< < 18 19 20 21 22 23 24 25 > >> 

You may also start an advanced similarity search for this article.