R. D. Seidgazov, “Thermocapillary mechanism of the laser penetration welding”, Mat. Model., 22:8 (2010), 67–82; Math. Models Comput. Simul., 3:2 (2011), 234

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Matematicheskoe modelirovanie, 2010, Volume 22, Number 8, Pages 67–82 (Mi mm3008)

This article is cited in 5 scientific papers (total in 5 papers)

Thermocapillary mechanism of the laser penetration welding

R. D. Seidgazov

Moscow, Russian Federation

Full-text PDF (351 kB) Citations (5)

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Abstract: The discrepancies between empirical data and the notions of the evaporative hypothesis, which assumes the melt displacement by vapor recoil pressure, are sufficient to cast doubt on the legitimacy of applying the evaporative hypothesis to the simulation of hydrodynamic processes in laser welding. To resolve these discrepancies, a hypothesis and theoretical model explaining keyhole formation as being due to tangential thermocapillary forces acting on a non-uniformly heated surface and the melt being removed from the beam impact zone is proposed. The keyhole phenomenon appears when the threshold beam intensity is exceeded and the thermocapillary divergent flow becomes structurally rearranged with the flow line rupture on the transition from a vortex flow to a shear flow. The thermocapillary model of keyhole formation is verified by comparing the calculated basic parameters of the process with empirical data.

Keywords: laser welding, deep penetration welding, keyhole formation, thermocapillary melt displacement.

Received: 21.12.2009

English version:
Mathematical Models and Computer Simulations, 2011, Volume 3, Issue 2, Pages 234–244
DOI: https://doi.org/10.1134/S2070048211020098

Bibliographic databases:

Document Type: Article

UDC: 621.393.826.038.824

Language: Russian

Citation: R. D. Seidgazov, “Thermocapillary mechanism of the laser penetration welding”, Mat. Model., 22:8 (2010), 67–82; Math. Models Comput. Simul., 3:2 (2011), 234–244

Citation in format AMSBIB

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\by R.~D.~Seidgazov

\paper Thermocapillary mechanism of the laser penetration welding

\jour Mat. Model.

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\vol 22

\issue 8

\pages 67--82

\mathnet{http://mi.mathnet.ru/mm3008}

\transl

\jour Math. Models Comput. Simul.

\yr 2011

\vol 3

\issue 2

\pages 234--244

\crossref{https://doi.org/10.1134/S2070048211020098}

\scopus{https://www.scopus.com/record/display.url?origin=inward&eid=2-s2.0-84929076724}

Linking options:

https://www.mathnet.ru/eng/mm3008

https://www.mathnet.ru/eng/mm/v22/i8/p67

This publication is cited in the following 5 articles:

R. D. Seidgazov, F. Kh. Mirzade, “Physical Substantiation of a Discretization Scheme in Modeling Deep Penetration Melting of Metals in Laser and Related Technologies”, Math Models Comput Simul, 17:1 (2025), 25
R. D. Seidgazov, F. Kh. Mirzade, “Fizicheskoe obosnovanie skhemy diskretizatsii pri modelirovanii glubokogo proplavleniya metallov v lazernykh i rodstvennykh tekhnologiyakh”, Matem. modelirovanie, 36:5 (2024), 41–54
R D Seidgazov, F Kh Mirzade, “Threshold conditions for thermocapillary transition to deep penetration mode in selective laser melting of metal powder bed”, IOP Conf. Ser.: Mater. Sci. Eng., 759:1 (2020), 012023
Chen B.C., Ho C.Y., Wen M.Y., Lin V.H., Lee Y.C., “Analytical Study on Deep Penetration Induced By Focused Moving High-Energy Beam”, Laser Part. Beams, 35:2 (2017), 193–201
Kochurin E.A., Lisenkov V.V., Osipov V.V., Platonov V.V., Zubarev N.M., “On the Mechanism of Deep Craters Formation Under the Action of High Power Ytterbium-Fiber Laser”, Xxxi International Conference on Equations of State For Matter (Elbrus 2016), Journal of Physics Conference Series, 774, IOP Publishing Ltd, 2016, UNSP 012121

Citing articles in Google Scholar: Russian citations, English citations
Related articles in Google Scholar: Russian articles, English articles

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Full-text PDF :	249
References:	77
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