Energy Density Dependence of Bonding Characteristics of Selective Laser-Melted Nb-Si-Based Alloy on Titanium Substrate

doi:10.1007/s40195-017-0670-8

Abstract

Abstract:

Spherical Nb-20Si-24Ti-2Cr-2Al pre-alloyed powders were processed by selective laser melting (SLM) on Ti6Al4V substrates with different energy densities. A series of single tracks and single layers were produced using different processing parameters, including powder size, laser power, scanning speed and hatch distance. Results showed that the pre-alloyed powders ranging from 45 to 75 μm were more applicable to SLM with less balling tendency, in comparison with those between 75 and 180 μm. The increase in linear energy density (LED) resulted in the decrease in contact angle and the increase in the width of single track as well as its penetration depth into the substrate. Smaller hatch distance leaded to a larger remelted part of the former track and a higher volumetric laser energy density. With a thickness of 75.6 μm, an interfacial intermediate layer, enriched in Ti and depleted in Nb, Si, Cr and Al, was formed between the SLM part and the Ti6Al4V substrate. The mechanisms of the elimination of balling phenomenon by employing a higher LED and the interfacial bonding characteristics between Nb-Si-based alloys via SLM and the Ti6Al4V substrate were discussed.

Key words: Nb-Si alloys, Selective laser melting, Additive manufacture, Bonding character, Microstructure

Yue-Ling Guo, Li-Na Jia, Bin Kong, Yong-Lin Huang, Hu Zhang. Energy Density Dependence of Bonding Characteristics of Selective Laser-Melted Nb-Si-Based Alloy on Titanium Substrate[J]. Acta Metallurgica Sinica (English Letters), 2018, 31(5): 477-486.

Figures/Tables 12

Fig. 1 Surface morphologies of Nb-Si pre-alloyed powders: a P1; b P2

Fig. 2 Surface morphologies of single tracks formed from P1 a and P2 b powders; c is the magnified image of the yellow rectangle in a, d is the magnified image of the red rectangle in a

Fig. 3 Width distributions of single tracks formed from P1 powders with different processing parameters (the error bars refer to standard deviation)

Fig. 4 a Cross-section morphology of single track formed from P1 powders (P = 380 W, V = 400 mm/s); b distributions of Nb, Si and Ti elements along line OA obtained using EPMA

Fig. 5 Schematic plot of contact angle (θ) and penetration depth (d) of single tracks a; penetration depth b and contact angle c on cross-sections of single tracks formed from P1 powders

Fig. 6 Cross-section morphologies of single layers formed from P1 with different hatch distances (H): a H = 50 μm; b H = 80 μm; c H = 120 μm; d H = 150 μm. The laser power is 380 W, and the scanning speed is 200 mm/s. The insets in the bottom show the macroscopic surface morphologies of the single layers processed with respective hatch distance

Fig. 7 Chemical maps of cross-sections of single layers formed from P1 with different hatch distances in sub-circular interfacial region: a BEI; b Nb; c Si; d Ti

Fig. 8 Top surface a and sectional microstructure b of cubic part built by optimized processing parameters

Fig. 9 Chemical maps of interface between Ti6Al4V substrate and Nb-Si-based alloy via SLM: a BEI; b Nb; c Si; d Ti; e Cr; f Al

Fig. 10 Distributions of Nb, Si, Ti, Cr and Al across interface between Ti6Al4V substrate and Nb-Si-based alloy via SLM

Fig. 11 Schematic diagram of SLM physical model

Fig. 12 Microstructural illustration of Nb-Si-based alloy processed by SLM on a Ti6Al4V substrate

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