Modeling of laser beam and powder flow interaction in laser cladding using ray-tracing

Devesse, Wim; Baere, Dieter De; Guillaume, Patrick

doi:10.2351/1.4906394

Cited by 51 publications

(4 citation statements)

References 11 publications

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“…The powder stream model described in this article could be used for more accurate DED-PF melt pool simulations that include a powder stream [35] and modeling a laser beam with the Gaussian beam ray representation could be used in simulations of laser interaction with metal powder in the laser powder bed fusion process [36,37].…”

Section: Credit Authorship Contribution Statementmentioning

confidence: 99%

Directed energy deposition powder stream modeling using a Gaussian beam ray representation

2022

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Section: Credit Authorship Contribution Statementmentioning

confidence: 99%

Directed energy deposition powder stream modeling using a Gaussian beam ray representation

2022

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“…In addition to the laser power, powder feed rate, and scanning speed, the z-increment is also an important parameter for the deposition of thin-wall parts, and it has significant influence on the surface roughness, dimension precision, and surface oxidation that was proved by researchers [32,65]. With the different z-increment, the thin-wall presents various contours during another parameter is same.…”

Section: Matching Of Z-increment and Single Deposition Heightmentioning

confidence: 99%

Macroscopic and Microstructural Features of Metal Thin-Wall Fabricated by Laser Material Deposition: A Review

et al. 2022

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Owing to the versatility without expanding the machine’s size, thin-wall has been widely used in high-value parts. The investigation of laser additive manufacturing (LAM), which has advantages such as high powder density, easy controllability, and excellent stability, on the fabrication of thin-wall has drawn much attention. In this paper, the research status of macroscopic and microstructural features of metal thin-wall fabricated by LAM has been reviewed. The deposition quality was mainly focused on the effect of process parameters and especially the matching of z-increment and single deposition height. Based on the grain size and growth of columnar, the characteristics of microstructures were analyzed. Considering the structural feature of thin-wall, the effect of grain size and phases on the hardness and distribution of hardness were discussed. The effect of grain size, phases and loading direction on the tensile properties were reviewed. The distribution and modification of thermal stress were presented.

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“…• Interactions between particles such as collisions or shadow effects are neglected [25], power losses due to second reflections are also neglected [26].…”

Section: /2mentioning

confidence: 99%

Estimation of track dimensions obtained in Laser Metal Deposition-powder thanks to a semi-analytical model coupled to an Eulerian thermal simulation

Leroy-Dubief¹,

Poulhaon²,

Joyot³

2021

Esaform 2021

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Originally issued from cladding, the LMD-p process widens the field of possibilities in terms of manufacturing. Depending on the targeted application, the needs regarding the track geometry are different and the ability to adapt it is a key challenge. In LMD-p, the laser beam attenuation as well as the powder particles preheating are both determined by laser-powder interactions before the powder reaches the substrate. The track dimensions are directly correlated to the melt pool size: a larger pool will tend to capture more powder resulting in a higher deposition rate. The model presented here intends to determine, for a given working distance, the partition of energy, and to estimate the area of the generated melt pool and finally the dimensions of the deposited track. It is first based on a semi-analytical approach that models the powder distribution and calculates the transmitted power to both substrate and powder particles. The attenuated power density is then an input for a light Eulerian thermal simulation from which the contour of the molten zone is extracted. Several iterations are carried out to account for the energy loss caused by the heating and melting of the powder entering the pool. Lastly, the track dimensions are estimated from the stabilized melt pool configuration. Track geometries obtained with a BeAM® machine are compared to the model predictions. Such an approach opens very interesting perspectives in studying the influence of the working distance and its optimization for a given material and/or a given application.

show abstract

Modeling of laser beam and powder flow interaction in laser cladding using ray-tracing

Cited by 51 publications

References 11 publications

Directed energy deposition powder stream modeling using a Gaussian beam ray representation

Directed energy deposition powder stream modeling using a Gaussian beam ray representation

Macroscopic and Microstructural Features of Metal Thin-Wall Fabricated by Laser Material Deposition: A Review

Estimation of track dimensions obtained in Laser Metal Deposition-powder thanks to a semi-analytical model coupled to an Eulerian thermal simulation

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