Preparation and Performance of Spherical Ni Powder for SLM Processing

doi:10.11900/0412.1961.2018.00153

Acta Metall Sin

2018, Vol. 54

Issue (12): 1833-1842 DOI: 10.11900/0412.1961.2018.00153

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Preparation and Performance of Spherical Ni Powder for SLM Processing

Yajuan ZHANG, Haibin WANG, Xiaoyan SONG, Zuoren NIE(

)

Key Laboratory of Advanced Functional Materials, Education Ministry of China, College of Materials Science and Engineering, Beijing University of Technology, Beijing 100124, China

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Yajuan ZHANG, Haibin WANG, Xiaoyan SONG, Zuoren NIE. Preparation and Performance of Spherical Ni Powder for SLM Processing. Acta Metall Sin, 2018, 54(12): 1833-1842.

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Abstract

3D printing has attracted increasing interests in the field of metallic materials as it can effectively shorten the production cycle and create parts with complex shapes, which can hardly be produced by traditional methods. However, the gas atomization, as the mainstream method of preparing metal and alloy powders to meet the requirements of the processing of selective laser melting (SLM) at present, still has some limitations, such as hollow and/or satellite balls in the powder. This influences directly the density and performance of the printing parts. Moreover, the laser absorption in the smooth surface of powder particle is generally less than 10% in the laser processing, which hinders rapid heating of the powder. It has been found that the material can obtain multiple absorption of laser energy by increasing the surface roughness of powder particles, which can effectively improve the laser absorption rate and is beneficial to get the dense printing parts. Based on this, a novel method combining low temperature spray-drying with heat treatment was developed to prepare Ni powder with high purity, good sphericity, high flowability and narrow particle size distribution. The microstructure and laser absorptivity of the prepared Ni powder were compared with those of the commercial Ni powder prepared by gas atomization, and their influences on the microstructure and properties of the 3D printed bulk materials were investigated. It is found that the laser absorptivity of the Ni powder prepared by spray-drying is more than 2 times as high as that of the commercial Ni powder. This leads to a wider melting channel, smaller surface tension and liquid-bridging force between particles in the printing process. As a result, the spheroidization phenomenon occurred on the surface of the printed bulk material can be avoided by the use of the spray-dried powder, and the relative density is achieved as 99.2% at the as-printed state. In the microstructure of the printed bulk material, in addition to the cellular crystals, there are a number of fine columnar crystals, grown across the interlaminar boundaries, which is favorable for a high bonding strength between the interlayers.

Key words: selective laser melting spray drying sphericity surface roughness laser absorptivity

Received: 19 April 2018

ZTFLH:

TF123

Fund: Supported by Innovation Research Groups of National Natural Science Foundation of China (No.51621003)

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	Yajuan ZHANG
	Haibin WANG
	Xiaoyan SONG
	Zuoren NIE

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https://www.ams.org.cn/EN/10.11900/0412.1961.2018.00153 OR https://www.ams.org.cn/EN/Y2018/V54/I12/1833

Fig.1 Morphologies (a, b) of the Ni powders for printing prepared by spray-drying (a) and commercial gas atomization (b), particles size distribution (c) and sphericity (d) of the Ni powders

Fig.2 Morphologies (a, c) and cross-sectional microstructures (b, d) of a single Ni particle prepared by spray drying (a, b) and gas atomization (c, d)

Table 1 Compositions of the spray-dried and gas atomized Ni powders (mass fraction / %)

Fig.3 XRD spectra of the Ni powders for 3D printing prepared by spray-drying and gas atomization

Fig.4 XRD spectra of the printed bulk materials prepared by spray-dried and gas atomized Ni powders

Fig.5 Morphologies of the as-printed surfaces (a, c) and polished surfaces (b, d) of the printed bulk materials prepared by spray-dried (a, b) and gas atomized (c, d) Ni powders

Fig.6 Surface profiles of the Ni powder particles prepared by spray-dring (a) and gas atomization (b)

Fig.7 Morphologies of the side surfaces (a, c) and polished surfaces (b, d) of the printed bulk materials prepared by spray-dried (a, b) and gas atomized (c, d) Ni powders (Arrows in Figs.7b and d show the equiaxed grains)

Fig.8 Comparison of microhardnesses of the Ni bulks printed by the gas atomized and spray-dried powders and the conventional cast ingot

Fig.9 Nanoindentation hardnesses of the printed bulk materials prepared by spray-dried Ni powder (a) and gas atomized Ni powder (b)

Fig.10 Displacement-loading curves of the printed bulk materials

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