Authors: N. Siva Shanmugam, G. Buvanashekaran, K. Sankaranarayanasamy

Abstract:

In this research work, investigations are carried out on Continuous Wave (CW) Nd:YAG laser welding system after preliminary experimentation to understand the influencing parameters associated with laser welding of AISI 304. The experimental procedure involves a series of laser welding trials on AISI 304 stainless steel sheets with various combinations of process parameters like beam power, beam incident angle and beam incident angle. An industrial 2 kW CW Nd:YAG laser system, available at Welding Research Institute (WRI), BHEL Tiruchirappalli, is used for conducting the welding trials for this research. After proper tuning of laser beam, laser welding experiments are conducted on AISI 304 grade sheets to evaluate the influence of various input parameters on weld bead geometry i.e. bead width (BW) and depth of penetration (DOP). From the laser welding results, it is noticed that the beam power and welding speed are the two influencing parameters on depth and width of the bead. Three dimensional finite element simulation of high density heat source have been performed for laser welding technique using finite element code ANSYS for predicting the temperature profile of laser beam heat source on AISI 304 stainless steel sheets. The temperature dependent material properties for AISI 304 stainless steel are taken into account in the simulation, which has a great influence in computing the temperature profiles. The latent heat of fusion is considered by the thermal enthalpy of material for calculation of phase transition problem. A Gaussian distribution of heat flux using a moving heat source with a conical shape is used for analyzing the temperature profiles. Experimental and simulated values for weld bead profiles are analyzed for stainless steel material for different beam power, welding speed and beam incident angle. The results obtained from the simulation are compared with those from the experimental data and it is observed that the results of numerical analysis (FEM) are in good agreement with experimental results, with an overall percentage of error estimated to be within ±6%.

Keywords: Laser welding, Butt weld, 304 SS, FEM.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1087241

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References:

[1] J.F. Ready and D.F. Farson, “LIA Handbook of Laser Materials Processing”, 1st ed., Magnolia Publishing, Laser Institute of America, 2001.
[2] S.A. Tsirkas, P. Papanikos and Th. Kermanidis, “Numerical simulation of the laser welding process in butt-joint specimens”, Journal of Materials Processing Technology, 134, pp 59-69, 2003.
[3] D. Rosenthal, “The Theory of Moving Source of Heat and it’s Application to Metal Treatment”, Trans. ASME, 68, pp. 849–866, 1946.
[4] D.T.S. Hook and A.E.F. Gick, “Penetration welding with lasers”, Welding Research Supplement, pp. 492s-498s, 1973
[5] M. Lax, “Temperature rise induced by a laser beam”, Journal of Applied Physics, 48, pp. 3919-3924, 1977.
[6] J. Dowden, M. Davis and P. Kapadia, “Some aspects of the fluid dynamics of laser welding”, Journal of Fluid Mechanics, 126, pp. 123- 146, 1983.
[7] R. Brockmann, K. Dickmann, P. Geshev and K. J. Matthes, “Calculation of temperature field in a thin moving sheet heated with laser beam”, International Journal of Heat and Mass Transfer, 46, pp. 717-723, 2003.
[8] A. Mahrle and J. Schmidt, “The influence of fluid flow phenomena on the laser welding process”, International Journal of Heat and Fluid Flow, 23, 288-297, 2002.
[9] A.P. Mackwood and R.C. Crafer, “Thermal modelling of laser welding and related processes: literature review”, Optics & Laser Technology, 37(2), pp. 99–115, 2005
[10] K.Y. Benyounis, A.G. Olabi and M.S.J. Hashmi, “Effect of laser welding parameters on the heat input and weld-bead profile”, Journal of Materials Processing Technology, 164–165, pp. 978–985, 2005.
[11] H. GuoMing, Z. Jian and L. JianQang, “Dynamic simulation of the temperature field of stainless steel laser welding”, Materials & Design, 28(1), pp. 240-245, 2007.
[12] D. Radaj, “Heat Effects of Welding, Temperature Field, Residual Stress, Distortion”, Springer-Verlag, Berlin, Heidelberg, New York, London, Paris, Tokyo, 1992.
[13] Z. Ji and S. Wu, “FEM Simulation of the temperature field during the laser forming of sheet metal”, Journal of Materials Processing Technology, 74(1-3), pp. 89-95, 1998.
[14] J. Sabbaghzadeh, M. Azizi and M.J. Torkamany, “Numerical and experimental investigation of seam welding with a pulsed laser”, Journal of Optics & Laser Technology, 40, pp. 289-296, 2008.
[15] W.S. Chang and S.J. Na, “Prediction of laser spot weld shape by numerical analysis and neural network”, Metallurgical and Material Transactions B, 32B, pp 723-731, August 2001.
[16] C.S. Wu, H.G. Wang and Y.M. Zhang, “A New Heat Source Model for Keyhole Plasma Arc Welding in FEM Analysis of the Temperature Profile”, Welding Journal, 85(12), pp. 284s-291s, 2006.
[17] J. Xie and A. Kar, “Laser Welding of Thin Sheet Steel with Surface Oxidation”, Welding Research Supplement, 78, pp. 343s – 348s, 1999.
[18] C. Carmignani, R. Mares and G. Toselli, “Transient finite element analysis of deep penetration laser welding process in a singlepass buttwelded thick steel plate”, Journal of Computational Methods in Applied Mechanics and Engineering, 179, pp. 197-124, 1999.
[19] W.R. Harp, A.G. Paleocrassas and J.F. Tu, “A Practical method for determining the beam profile near the focal spot”, International Journal of Advanced Manufacturing Technology, 37(11-12), pp. 1113-1119. 2007.
[20] ANSYS® Release 9.0 Documentation Chapter 3.9 Phase Change (data accessed on 29.01.2009)
[21] M.R. Frewin and D.A. Scott, “Finite Element Model of Pulsed Laser Welding”, Welding Research Supplement, 78, 15s-22s, 1999.