Impact of gas flow direction on the crystallographic texture evolution in laser beam powder bed fusion

Hiroki Amano; Takuya Ishimoto; Koji Hagihara; Ryoya Suganuma; Keisuke Aiba; Shi Hai Sun; Pan Wang; Takayoshi Nakano

doi:10.1080/17452759.2023.2169172

Impact of gas flow direction on the crystallographic texture evolution in laser beam powder bed fusion

Hiroki Amano, Takuya Ishimoto, Koji Hagihara, Ryoya Suganuma, Keisuke Aiba, Shi Hai Sun, Pan Wang, Takayoshi Nakano^*

^*Corresponding author for this work

School of Material Science and Engineering

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

This study demonstrated that the gas flow direction in the laser beam powder bed fusion (PBF-LB) significantly affects the crystallographic texture evolved in the products. The effect on texture is attributed to the difference in the melt pool depth, which depends on gas flow direction. The melt pool was shallower when the laser scanning and gas flow directions were parallel than when they were perpendicular. This phenomenon should be of particular concern when applying Scan Strategy_XY wherein the laser was scanned with a 90° rotation in each layer, which is often used in PBF-LB. The asymmetry in the melt pool depth generated by laser scanning in the x- and y-directions can lead to unintended variations in the crystallographic texture. The gas phase would interact with a part being manufactured immediately beneath the gas and affect the crystallographic feature of the product.

Original language	English
Article number	e2169172
Journal	Virtual and Physical Prototyping
Volume	18
Issue number	1
DOIs	https://doi.org/10.1080/17452759.2023.2169172
Publication status	Published - 2023

Keywords

Gas flow direction
crystallographic orientation
laser powder bed fusion
scan strategy
thermal conductivity

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10.1080/17452759.2023.2169172

Cite this

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title = "Impact of gas flow direction on the crystallographic texture evolution in laser beam powder bed fusion",

abstract = "This study demonstrated that the gas flow direction in the laser beam powder bed fusion (PBF-LB) significantly affects the crystallographic texture evolved in the products. The effect on texture is attributed to the difference in the melt pool depth, which depends on gas flow direction. The melt pool was shallower when the laser scanning and gas flow directions were parallel than when they were perpendicular. This phenomenon should be of particular concern when applying Scan Strategy_XY wherein the laser was scanned with a 90° rotation in each layer, which is often used in PBF-LB. The asymmetry in the melt pool depth generated by laser scanning in the x- and y-directions can lead to unintended variations in the crystallographic texture. The gas phase would interact with a part being manufactured immediately beneath the gas and affect the crystallographic feature of the product.",

keywords = "Gas flow direction, crystallographic orientation, laser powder bed fusion, scan strategy, thermal conductivity",

author = "Hiroki Amano and Takuya Ishimoto and Koji Hagihara and Ryoya Suganuma and Keisuke Aiba and Sun, {Shi Hai} and Pan Wang and Takayoshi Nakano",

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AU - Amano, Hiroki

AU - Ishimoto, Takuya

AU - Hagihara, Koji

AU - Suganuma, Ryoya

AU - Aiba, Keisuke

AU - Sun, Shi Hai

AU - Wang, Pan

AU - Nakano, Takayoshi

PY - 2023

Y1 - 2023

N2 - This study demonstrated that the gas flow direction in the laser beam powder bed fusion (PBF-LB) significantly affects the crystallographic texture evolved in the products. The effect on texture is attributed to the difference in the melt pool depth, which depends on gas flow direction. The melt pool was shallower when the laser scanning and gas flow directions were parallel than when they were perpendicular. This phenomenon should be of particular concern when applying Scan Strategy_XY wherein the laser was scanned with a 90° rotation in each layer, which is often used in PBF-LB. The asymmetry in the melt pool depth generated by laser scanning in the x- and y-directions can lead to unintended variations in the crystallographic texture. The gas phase would interact with a part being manufactured immediately beneath the gas and affect the crystallographic feature of the product.

AB - This study demonstrated that the gas flow direction in the laser beam powder bed fusion (PBF-LB) significantly affects the crystallographic texture evolved in the products. The effect on texture is attributed to the difference in the melt pool depth, which depends on gas flow direction. The melt pool was shallower when the laser scanning and gas flow directions were parallel than when they were perpendicular. This phenomenon should be of particular concern when applying Scan Strategy_XY wherein the laser was scanned with a 90° rotation in each layer, which is often used in PBF-LB. The asymmetry in the melt pool depth generated by laser scanning in the x- and y-directions can lead to unintended variations in the crystallographic texture. The gas phase would interact with a part being manufactured immediately beneath the gas and affect the crystallographic feature of the product.

KW - Gas flow direction

KW - crystallographic orientation

KW - laser powder bed fusion

KW - scan strategy

KW - thermal conductivity

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Impact of gas flow direction on the crystallographic texture evolution in laser beam powder bed fusion

Abstract

Keywords

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