Process planning and optimisation of laser cladding considering hydrodynamics and heat dissipation geometry of parts

Process planning and optimisation of laser cladding considering hydrodynamics and heat dissipation geometry of parts

A hydrodynamic model has been developed, which allows planning the laser cladding process, taking into account the heat dissipation geometry. Typical situations of heat dissipation are considered at 3D parts printing: diffusion into a massive substrate, the edge of a massive part, and a thin wall. T...

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Veröffentlicht in:Quantum electronics (Woodbury, N.Y.) N.Y.), 2018-09, Vol.48 (8), p.743-748
Hauptverfasser: Niz'ev, V.G., Khomenko, M.D., Mirzade, F.Kh
Format: Artikel
Sprache:eng
Schlagworte:
CLADDING
CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS
Computational fluid dynamics
direct numerical simulation
Fluid flow
GEOMETRY
HEAT TRANSFER
heat-dissipation geometry
HYDRODYNAMIC MODEL
HYDRODYNAMICS
Laser beam cladding
laser cladding
LASERS
OPTIMIZATION
Process planning
SUBSTRATES
THERMAL DIFFUSIVITY
THERMAL EFFLUENTS
Thin walls
Three dimensional printing
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Zusammenfassung:A hydrodynamic model has been developed, which allows planning the laser cladding process, taking into account the heat dissipation geometry. Typical situations of heat dissipation are considered at 3D parts printing: diffusion into a massive substrate, the edge of a massive part, and a thin wall. The laser power regimes are determined for different heat-dissipation geometries. The possibility of high-quality laser cladding at small turning radii is shown.
ISSN:1063-7818
1468-4799
DOI:10.1070/QEL16708