Influence of Island Scanning Strategy on Microstructures and Mechanical Properties of Direct Laser-Deposited Ti-6Al-4V Structures

doi:10.1007/s40195-018-0858-6

Abstract

Abstract:

To investigate the influence of island scanning on the microstructures and mechanical properties of direct laser-deposited Ti-6Al-4V structures, two samples are prepared using island scanning and orthogonal successive scanning, respectively. The microstructures, relative density, and mechanical properties of the samples prepared using these two scanning strategies are compared. Each sample exhibits columnar β-grain morphology and basket-weave microstructure characterization. The grains of the sample prepared using island scanning are significantly finer than that prepared by orthogonal successive scanning due to faster cooling during deposition. However, the relative density of the sample prepared using island scanning was slightly smaller due to the concentration of lack-of-fusion pores at the overlap zone of the island. Tensile testing at room temperature indicates that the ultimate tensile strength and yield strength of the sample prepared using island scanning is enhanced due to finer grains, while the ductility of the sample is weakened due to defects.

Key words: Direct laser deposition, Ti-6Al-4V, Scanning strategies, Microstructure, Defects, Mechanical property

Xiao Wang, Fei Lv, Li-Da Shen, Hui-Xin Liang, De-Qiao Xie, Zong-Jun Tian. Influence of Island Scanning Strategy on Microstructures and Mechanical Properties of Direct Laser-Deposited Ti-6Al-4V Structures[J]. Acta Metallurgica Sinica (English Letters), 2019, 32(9): 1173-1180.

Figures/Tables 9

Fig. 1 SEM image of morphology of Ti-6Al-4V powders

Fig. 2 Direct laser-deposited Ti-6Al-4V structures (mm): a build dimension; b laser scanning path of orthogonal successive scanning on even layers; c laser scanning path of island scanning

Fig. 3 Macrostructure and microstructure of samples: a macrostructure by orthogonal scanning; b macrostructure by island scanning; c intragranular α phase feature by orthogonal scanning; d intragranular α phase feature o by island scanning

Fig. 4 Relative density of samples by different scanning strategies

Fig. 5 Interior quality of direct laser-deposited samples by different scanning strategies: a, c orthogonal successive scanning; b, d island scanning

Fig. 6 Overlapping types by different scanning strategies: a conventional successive scanning; b island scanning

Fig. 7 Tensile stress-strain curves of specimens by different scanning strategies: a horizontal samples; b vertical samples

Table 1 Tensile properties of specimens by different scanning strategies (σ0.2: yield strength; σb: tensile strength; δ: elongation; Ψ: section shrinkage)

	σ_0.2 (MPa)	σ_b (MPa)	δ (%)	Ψ (%)
Successive horizontal	917	829	13.1	49.6
Island horizontal	966	890	12.2	48.4
Successive vertical	918	838	15.8	51.8
Island vertical	970	917	17.2	50.4

Fig. 8 SEM micrographs of fracture surfaces of specimens by different scanning strategies: a, e horizontal specimen by orthogonal successive scanning; b, f horizontal specimen by island scanning; c, g vertical specimen by orthogonal successive scanning; d, h vertical specimen by island scanning

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