Modeling the Process of Laser Cladding in an External Acoustic Field to Determine the Effect of Ultrasound Intensity on the Morphology of the Cladding Layer

A mathematical model of laser cladding in a three-dimensional non-stationary approximation was developed, which makes it possible to consider the ultrasonic effect on the melt pool and the cladding layer during its solidification. The model equations are solved by the finite element method (strength...

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Veröffentlicht in:	Russian aeronautics 2021-07, Vol.64 (3), p.540-546
Hauptverfasser:	Khamidullin, B. A., Tsivil’skii, I. V., Gil’mutdinov, A. Kh
Format:	Artikel
Sprache:	eng
Schlagworte:	Acoustic waves Aircraft Production Technology Automotive Engineering Engineering Finite element method Heat affected zone Laser beam cladding Mass transfer Mathematical analysis Mathematical models Solidification
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description	A mathematical model of laser cladding in a three-dimensional non-stationary approximation was developed, which makes it possible to consider the ultrasonic effect on the melt pool and the cladding layer during its solidification. The model equations are solved by the finite element method (strength) and finite volumes (heat and mass transfer) and allow you to calculate the dimensions of the deposited layer, melt pool, and heat affected zone with varying modes. The distribution of acoustic waves on the surface of the product was verified experimentally by the method of Chladni figures.
doi_str_mv	10.3103/S1068799821030235
format	Article
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subjects	Acoustic waves Aircraft Production Technology Automotive Engineering Engineering Finite element method Heat affected zone Laser beam cladding Mass transfer Mathematical analysis Mathematical models Solidification
title	Modeling the Process of Laser Cladding in an External Acoustic Field to Determine the Effect of Ultrasound Intensity on the Morphology of the Cladding Layer
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