Three‐dimensional computational modelling of momentum, heat and mass transfer in laser surface alloying with distributed melting of alloying element

Raj, P. Mohan; Sarkar, Supriya; Chakraborty, Suman; Dutta, Pradip

doi:10.1108/eum0000000005669

Cited by 16 publications

(2 citation statements)

References 10 publications

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“…Hence, the turbulent bursting in the welding pool is generated during the laser-welding process. The similar phenomena can be seen elsewhere [12][13][14][15][16][17][18][19]. Fig.…”

Section: Resultssupporting

confidence: 71%

Interface microstructure and mechanical properties of laser welding copper–steel dissimilar joint

Yao

Xu²,

Zhang

et al. 2009

Optics and Lasers in Engineering

181

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“…Hence, the turbulent bursting in the welding pool is generated during the laser-welding process. The similar phenomena can be seen elsewhere [12][13][14][15][16][17][18][19]. Fig.…”

Section: Resultssupporting

confidence: 71%

Interface microstructure and mechanical properties of laser welding copper–steel dissimilar joint

Yao

Xu²,

Zhang

et al. 2009

Optics and Lasers in Engineering

181

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“…(ii) As the power density is low and there is no external gas pressure, the free surface is assumed planar. Similar laser processes involving melting have been modelled in the past with the assumption of planar free surface with reasonable accuracy [11,12,[17][18][19][20][21][22]. (iii) Radiation effects are neglected.…”

Section: Governing Equationsmentioning

confidence: 97%

Numerical analysis of the effects of non-conventional laser beam geometries during laser melting of metallic materials

Safdar¹,

Li²,

Sheikh³

2007

J. Phys. D: Appl. Phys.

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Laser melting is an important industrial activity encountered in a variety of laser manufacturing processes, e.g. selective laser melting, welding, brazing, soldering, glazing, surface alloying, cladding etc. The majority of these processes are carried out by using either circular or rectangular beams. At present, the melt pool characteristics such as melt pool geometry, thermal gradients and cooling rate are controlled by the variation of laser power, spot size or scanning speed. However, the variations in these parameters are often limited by other processing conditions. Although different laser beam modes and intensity distributions have been studied to improve the process, no other laser beam geometries have been investigated. The effect of laser beam geometry on the laser melting process has received very little attention. This paper presents an investigation of the effects of different beam geometries including circular, rectangular and diamond shapes on laser melting of metallic materials. The finite volume method has been used to simulate the transient effects of a moving beam for laser melting of mild steel (EN-43A) taking into account Marangoni and buoyancy convection. The temperature distribution, melt pool geometry, fluid flow velocities and heating/cooling rates have been calculated. Some of the results have been compared with the experimental data.

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Laser Micro and Nano Processing of Metals , Ceramics , and Polymers

Pfleging

Kohler

Südmeyer

et al. 2012

Laser-Assisted Fabrication of Materials

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Three‐dimensional computational modelling of momentum, heat and mass transfer in laser surface alloying with distributed melting of alloying element

Cited by 16 publications

References 10 publications

Interface microstructure and mechanical properties of laser welding copper–steel dissimilar joint

Interface microstructure and mechanical properties of laser welding copper–steel dissimilar joint

Numerical analysis of the effects of non-conventional laser beam geometries during laser melting of metallic materials

Laser Micro and Nano Processing of Metals , Ceramics , and Polymers

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