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Single-track investigation of IN738LC superalloy fabricated by laser powder bed fusion: Track morphology, bead characteristics and part quality

•Single-track laser powder bed fusion experiments were performed on IN738LC.•Bead dimension varied significantly with respect to used processing parameters.•Balling occurred when solidification time was less than spread time of droplets.•Conduction mode transferred to keyhole as normalized enthalpy...

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Bibliographic Details
Published in:Journal of materials processing technology 2021-04, Vol.290, p.117000, Article 117000
Main Authors: Guo, Chuan, Xu, Zhen, Zhou, Yang, Shi, Shi, Li, Gan, Lu, Hongxing, Zhu, Qiang, Ward, R. Mark
Format: Article
Language:English
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Summary:•Single-track laser powder bed fusion experiments were performed on IN738LC.•Bead dimension varied significantly with respect to used processing parameters.•Balling occurred when solidification time was less than spread time of droplets.•Conduction mode transferred to keyhole as normalized enthalpy was larger than ∼ 50.•High porosity appeared in bulk samples at both low and high energy input densities. Single-track experiments were performed to investigate how the scan speed and the laser power affected the behavior of the single tracks during laser powder bed fusion, including the track stability, the melt pool dimension and the bead mode, using the nickel-based superalloy IN738LC. The processing parameters had an evident effect on the track morphology and the bead features in the experimental conditions investigated. The balling phenomenon was studied by a competitive model between the spread and the solidification of droplets. The analysis and experimental results clearly demonstrated that the track lost its stability when the droplets solidified before they spread out on the substrate with a contact angle greater than 90°. The keyhole mode was investigated by establishing the relationship between the normalized enthalpy and the normalized bead depth. The conduction mode would convert to the keyhole mode as normalized enthalpy was greater than ∼ 50. Finally, bulk samples were built with the same parameters as the single-track testing. It can be seen that the parts with high porosity appeared at both low and high energy input densities due to the un-melted powders and the keyhole pores, respectively.
ISSN:0924-0136
1873-4774
DOI:10.1016/j.jmatprotec.2020.117000