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Numerical and experiment study of residual stress and strain in multi-pass GMA welding

Wybrane pełne teksty z tego czasopisma
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Purpose: Recently, manufacturing industries have been concentrated on selection an optimal of welding parameter and condition that reduces the risk of mechanical failures on weld structures should be required in manufactory industry. In robotic GMA (Gas Metal Arc) welding process, heat and mass inputs are coupled and transferred by the weld arc to the molten weld pool and by the molten metal that is being transferred to the weld pool. The amount and distribution of the input energy are basically controlled by the obvious and careful choices of welding process parameters in order to accomplish the optimal bead geometry and the desired mechanical properties of the quality weldment. The residual stress and welding deformation have the large impact on the failure of welded structures. Design/methodology/approach: To achieve the required precision for welded structures, it is required to predict the welding distortions at the early stages. Therefore, this study represented 2D Finite Element Method (FEM) to predict residual stress and strain on thick SS400 steel metal plate. Findings: The experiment for Gas Metal Arc (GMA) welding process is also performed with similar welding condition to validate the FE results. The simulated and experiment results provide good evidence that heat input is main dependent on the welding parameter and residual stress and distortions are mainly affected by amount on heat input during each weld-pass. Practical implications: This present study on based on the numerical analysis using ansys software, for a thick multi-pass GMA welding. A birth and death technique is employed to control the each weld pass welding. Originality/value: The developed 2D multi-pass model employs Goldak’s heat distribution, to simulate welding on SS400 steel butt-weld joint with a thickness of 16mm. moreover the numerical results are validated with experiment results.
Rocznik
Strony
31--37
Opis fizyczny
Bibliogr. 18 poz., rys., tab.
Twórcy
autor
  • Mechanical Engineering, The University of the South Pacific, Suva, Fiji
autor
  • Department of Mechanical Engineering, Mokpo National University, 61, Dorim-ri, Chungkye-myun, Muan-gun, Chonnam, 534-729, Republic of Korea
autor
  • Department of Mechanical Engineering, Mokpo National University, 61, Dorim-ri, Chungkye-myun, Muan-gun, Chonnam, 534-729, Republic of Korea
autor
  • Department of Mechanical Engineering, Mokpo National University, 61, Dorim-ri, Chungkye-myun, Muan-gun, Chonnam, 534-729, Republic of Korea
autor
  • Mokpo Campus of Korea Polytechnic, 1854-16, Yeongsan-ro, Cheonggye-myeon, Muan-gun, Chonnam, 534-703, Republic of Korea
Bibliografia
  • [1] C. Heinze, C. Schwenk, M. Rethmeier, Numerical calculation of residual stress development of multi-pass gas metal arc welding under restraint conditions, Materials and Design Materials and Design 35 (2012) 201-209.
  • [2] D. Deng, FEM prediction of welding residual stress and distortion in carbon steel considering phase transformation effects, Materials and Design 30/2 (2009) 359-366.
  • [3] D. Deng, H. Murakawa, Prediction of welding distortion and residual stress in a thin plate butt-welded joint, Computational Materials Science 43 (2008) 353-365.
  • [4] D. Gery, H. Long, P. Maropoulos, Effects of welding speed, energy input and heat source distribution on temperature variations in butt joint welding, Journal of Materials Processing Technology 167 (2005) 393-401.
  • [5] D. Deng, W. Liang, H. Murakawa, Determination of welding deformation in fillet-welded joint by means of numerical simulation and comparison with experimental measurements, Journal of Materials Processing Technology 183/2-3 (2007) 219-225.
  • [6] E.M. Qureshi, A.M. Malik, N.U. Dar, Residual stress fields due to varying tack welds orientation in circumferentially welded thin-walled cylinders international, Journal of Advances in Mechanical Engineering (2009).
  • [7] C. Liu, J.X. Zhang, C.B. Xue, Numerical Investigation on residual stress distribution and evolutions during multi-pass narrow gap welding of thick-welled stainless steel pipes, Journal of Fusion Engineering and Design 86 (2011) 288-295.
  • [8] Sattari-Far, Y. Javadi, Influence of welding sequence on welding distortions in pipes, International Journal of Pressure Vessels and Piping 85/4 (2008) 265-274.
  • [9] J.A. Goldak, M. Akhlaghi, Computational welding Mechanics Springer, 2005.
  • [10] J. Goldak, M. Bibby, J. Moore, R. House, B. Patel, Computer modeling of heat flow in welds, Metallurgical Transactions B 17/3 (1986) 587-600.
  • [11] J. Goldak, A. Chakravarti, M. Bibby, A new finite element model for welding heat source, International Journal Metallurgical and Materials Transactions B 15/2 (1984) 299-305.
  • [12] P. Duranton, J. Devaux, V. Robin, P. Gilles, J.M. Bergheau, 3D modeling of multi-pass welding of a 316L stainless steel pipe, Journal Materials Processing Technology 153-154 (2004) 457-463.
  • [13] N.T. Nguyen, T.A. Ohta, K. Matsuoka, N. Suzuki, Y. Maeda, Analytical solutions for transient temperature of semi-infinite body subjected to 3-D moving heat sources, Welding Journal (1999) 265-274.
  • [14] H. Long, D. Gery, A. Carlier, P.S. Maropoulos, Prediction of welding distortion in butt joint of thin plates, Jounral of Material and Design 30 (2009) 4126-4135.
  • [15] De, S.K. Maiti, C.A. Walsh, H.K.D.H. Bhadeshia, Finite element simulation of laser spot welding, Science and Technology of Welding and Joining 8 (2003) 377-384.
  • [16] A.M. Malik, E.M. Qureshi, N.U. Dar, I. Khan, Analysis of circumferentially arc welded thin-walled cylinders to investigate the residual stress fields, Thin-Walled Structures, 46/12 (2008) 1391-1401.
  • [17] Z.B. Dong, Y.H. Wei, Three dimensional modeling weld solidification cracks in multi-pass welding, Theoretical and Applied Fracture Mechanics 46/2 (2006) 156-165.
  • [18] D. Deng, H. Murakawa, W. Liang, Numerical simulation of welding distortion in large structures, Computer Methods in Applied Mechanics and Engineering 196 (2007) 4613-4627.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-dbd55641-d74f-4ffd-9586-049c5614e585
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