A new strategy for the numerical modeling of a weld pool

A fundamental study of welding nozzle flow under cold flow conditions is presented. The aim is to examine the shielding gas flow characteristics for several Gas Metal Arc Welding (GMAW) flow conditions. Experimental investigations and numerical modeling are used to predict the flow behaviour of the gas shielding the weld pool. Results are presented for generic GMAW nozzle configurations at typical welding situations under cold flow. Flow visualization and Particle Image Velocimetry (PIV) reveal the various flow characteristics that are crucial to optimization of weld pool protection by the shielding gas. Numerical modeling of the flow is performed at conditions similar to the PIV experiments using the k-ε turbulence model in a commercial CFD package. Numerical predictions of the mean velocities agree reasonably well with PIV experiments, particularly in the radial wall jet region of the flow field. However, the turbulent kinetic energy is greatly over-predicted due to the eddy-viscosity stress-strain approximation in the k-ε model.

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NUMERICAL STUDY FOR GTA WELD SHAPE VARIATION BY COUPLING WELDING ARC AND WELD POOL

International Journal of Modern Physics B ◽

10.1142/s0217979209061329 ◽

2009 ◽

Vol 23 (06n07) ◽

pp. 1597-1602 ◽

Cited By ~ 1

Author(s):

WENCHAO DONG ◽

SHANPING LU ◽

DIANZHONG LI ◽

YIYI LI

Keyword(s):

Numerical Modeling ◽

Oxygen Content ◽

Weld Pool ◽

Drag Force ◽

Numerical Study ◽

Welding Current ◽

Gta Welding ◽

Weld Shape ◽

High Oxygen Content ◽

Welding Arc

A numerical modeling of the welding arc and weld pool is studied for moving GTA welding to investigate the effect of the surface active element oxygen and the plasma drag force on the weld shape. Based on the 2D axisymmetric numerical modeling of the argon arc, the heat flux, current density and plasma drag force are obtained under different welding currents. Numerical calculations to the weld pool development are carried out for moving GTA welding on SUS304 stainless steel with different oxygen contents 30 ppm and 220 ppm, respectively. The results show that the plasma drag force is another dominating driving force affecting the liquid pool flow pattern, except for the Marangoni force. The different welding currents will change the temperature distribution and plasma drag force on the pool surface, and affect the strength of Marangoni convection and the weld shape. The weld D/W ratio initially increases, followed by a constant value around 0.5 with the increasing welding current under high oxygen content. The weld D/W ratio under the low oxygen content slightly decreases with the increasing welding current. The predicted weld shape by simulation agrees well with experimental results.

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Numerical modeling of fluid flow, heat, and mass transfer for similar and dissimilar laser welding of Ti-6Al-4V and Inconel 718

The International Journal of Advanced Manufacturing Technology ◽

10.1007/s00170-021-06868-z ◽

2021 ◽

Author(s):

Amir Hossein Faraji ◽

Carmine Maletta ◽

Giuseppe Barbieri ◽

Francesco Cognini ◽

Luigi Bruno

Keyword(s):

Mass Transfer ◽

Numerical Modeling ◽

Fluid Flow ◽

Laser Welding ◽

Weld Pool ◽

Inconel 718 ◽

Dissimilar Welding ◽

Flow Heat ◽

Pool Formation ◽

Dissimilar Laser Welding

AbstractMost of the researches published on the numerical modeling of laser welding are looking at similar welding, mainly due to the difficulty of simulating the mixing phenomenon that occurs in dissimilar welding. Furthermore, numerical modeling of dissimilar laser welding of titanium and nickel alloys has been rarely reported in the literature. In this study, a 3D finite volume numerical model is proposed to simulate fluid flow, heat, and mass transfer for similar and dissimilar laser welding of Ti-6Al-4V and Inconel 718. The laser source was simulated by volumetric heat distribution, which considers the effects of keyhole and heat transfer on the workpiece. The heat source parameters were calibrated through preliminary experiments, by comparing the simulated and experimental weld pool shapes and dimensions. The model was used to simulate both homogenous and dissimilar laser weldings of Ti-6Al-4V and Inconel 718, and a systematic comparison was carried out through a number of selected experiments. The effects of three distinct levels of laser power (1.25 kW, 1.5 kW, 2.5 kW) on temperature distribution and velocity field in the welds pool were analyzed. Results highlighted the effects of Marangoni forces in the weld pool formation. Furthermore, in order to analyze the mass transfer phenomenon in dissimilar welding, species transfer equations were considered, demonstrating the important role played by the mass mixture in the weld pool formation. Finally, a high level of agreement between simulations and experiments—in terms of weld pool shape and dimensions—was observed in all cases analyzed. This proves the ability of the proposed numerical model to properly simulate both the similar and dissimilar welding of Ti-6Al-4V and Inconel 718 alloys.

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