2022
DOI: 10.3390/ma15144754
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Basic Mechanism of Surface Topography Evolution in Electron Beam Based Additive Manufacturing

Abstract: This study introduces and verifies a basic mechanism of surface topography evolution in electron beam additive manufacturing (E-PBF). A semi-analytical heat conduction model is used to examine the spatio-temporal evolution of the meltpool and segment the build surface according to the emerging persistent meltpool domains. Each persistent domain is directly compared with the corresponding melt surface, and exhibits a characteristic surface morphology and topography. The proposed underlying mechanism of topograp… Show more

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Cited by 8 publications
(9 citation statements)
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“…In order to understand the observed phenomena, it is essential to take a closer look at the influence of the process parameters on the melting conditions in PBF additive manufacturing. The interaction of beam power, scan velocity, and line offset can affect the melt pool dimensions, [32,34,55,56] melt pool dynamics, [23] and thermal boundary conditions [34,35,38,57] of the process.…”
Section: Discussionmentioning
confidence: 99%
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“…In order to understand the observed phenomena, it is essential to take a closer look at the influence of the process parameters on the melting conditions in PBF additive manufacturing. The interaction of beam power, scan velocity, and line offset can affect the melt pool dimensions, [32,34,55,56] melt pool dynamics, [23] and thermal boundary conditions [34,35,38,57] of the process.…”
Section: Discussionmentioning
confidence: 99%
“…Depending on the process parameters and the scanning strategy, different degrees of remelting and varying thermal boundary conditions may occur locally within each layer, which could be partly responsible for the emergence of bulges in distinct patterns. In a recent research paper, Breuning et al [57] proposed an additional explanation for the occurrence of pronounced bulges in certain areas of the surface: At high beam currents and scan velocities, the melt pool regime can change from a lens-shaped trailing melt pool to a persistent melt pool, that is, the melt pool is still active when the beam returns to the same position in the adjacent scan line. [56,57,61] If, for example, a rectangular area is melted with a snake-like scan strategy, a persistent melt pool regime may occur near the turning points, whereas the melt in the center of that area is already completely solidified within the beam return time.…”
Section: Discussionmentioning
confidence: 99%
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“…The recommended melt depth for EB-PBF is between 1.5 and 4 times the layer thickness used in the printing process, but according to the literature as long as the melt depth is larger than the layer thickness it is deemed as sufficient. [39,40] Usually finding the optimum parameter sets for a powder requires some sacrifice in either surface roughness, amount of pores seen in the material, or printing time. As previously stated, the power was one parameter studied and evaluated for the different substrates.…”
Section: Effect Of Power Variation On Melting Characteristicsmentioning
confidence: 99%