Denudation of metal powder layers in laser powder bed fusion processes

Denudation of metal powder layers in laser powder bed fusion processes

Understanding laser interaction with metal powder beds is critical in predicting optimum processing regimes in laser powder bed fusion additive manufacturing of metals. In this work, we study the denudation of metal powders that is observed near the laser scan path as a function of laser parameters...

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Veröffentlicht in:Acta materialia 2016-08, Vol.114 (C), p.33-42
Hauptverfasser: Matthews, Manyalibo J., Guss, Gabe, Khairallah, Saad A., Rubenchik, Alexander M., Depond, Philip J., King, Wayne E.
Format: Artikel
Sprache:eng
Schlagworte:
Defects
ENGINEERING
Finite element modeling
Fluid dynamics
Flux
Gas pressure
High speed imaging
Lasers
MATERIALS SCIENCE
Melt pools
Melts
Metal powders
Metal vapors
Powder bed fusion
Selective laser melting
Surface structure
Tracking
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container_end_page 42
container_issue C
container_start_page 33
container_title Acta materialia
container_volume 114
creator Matthews, Manyalibo J.
Guss, Gabe
Khairallah, Saad A.
Rubenchik, Alexander M.
Depond, Philip J.
King, Wayne E.
description Understanding laser interaction with metal powder beds is critical in predicting optimum processing regimes in laser powder bed fusion additive manufacturing of metals. In this work, we study the denudation of metal powders that is observed near the laser scan path as a function of laser parameters and ambient gas pressure. We show that the observed depletion of metal powder particles in the zone immediately surrounding the solidified track is due to a competition between outward metal vapor flux directed away from the laser spot and entrainment of powder particles in a shear flow of gas driven by a metal vapor jet at the melt track. Between atmospheric pressure and ∼10 Torr of Ar gas, the denuded zone width increases with decreasing ambient gas pressure and is dominated by entrainment from inward gas flow. The denuded zone then decreases from 10 to 2.2 Torr reaching a minimum before increasing again from 2.2 to 0.5 Torr where metal vapor flux and expansion from the melt pool dominates. The dynamics of the denudation process were captured using high-speed imaging, revealing that the particle movement is a complex interplay among melt pool geometry, metal vapor flow, and ambient gas pressure. The experimental results are rationalized through finite element simulations of the melt track formation and resulting vapor flow patterns. The results presented here represent new insights to denudation and melt track formation that can be important for the prediction and minimization of void defects and surface roughness in additively manufactured metal components. [Display omitted]
doi_str_mv 10.1016/j.actamat.2016.05.017
format Article
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The dynamics of the denudation process were captured using high-speed imaging, revealing that the particle movement is a complex interplay among melt pool geometry, metal vapor flow, and ambient gas pressure. The experimental results are rationalized through finite element simulations of the melt track formation and resulting vapor flow patterns. The results presented here represent new insights to denudation and melt track formation that can be important for the prediction and minimization of void defects and surface roughness in additively manufactured metal components. 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source Elsevier ScienceDirect Journals Complete
subjects Defects
ENGINEERING
Finite element modeling
Fluid dynamics
Flux
Gas pressure
High speed imaging
Lasers
MATERIALS SCIENCE
Melt pools
Melts
Metal powders
Metal vapors
Powder bed fusion
Selective laser melting
Surface structure
Tracking
title Denudation of metal powder layers in laser powder bed fusion processes
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