Improvement of Surface Mechanical and Tribological Characteristics of L-PBF Processed Commercially Pure Titanium through Ultrasonic Impact Treatment

IF 2.9 2区材料科学 Q2 METALLURGY & METALLURGICAL ENGINEERING

Acta Metallurgica Sinica-English Letters Pub Date : 2024-04-09 DOI:10.1007/s40195-024-01696-y

Iman Ansarian, Reza Taghiabadi, Saeid Amini, Mohammad Hossein Mosallanejad, Luca Iuliano, Abdollah Saboori

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Abstract

Multi-pass ultrasonic impact treatment (UIT) was applied to modify the microstructure and improve the mechanical and tribological characteristics at the near-surface region of commercially pure Ti (CP-Ti) specimens produced by the laser powder bed fusion (L-PBF) method. UIT considerably refined the L-PBF process-related acicular martensites (α′-M) and produced a well-homogenized and dense surface microstructure, where the porosity content of 1-, 3-, and 5-pass UITed samples was reduced by 43, 60, and 67%, respectively. The UITed samples showed an enhancement in their near-surface mechanical properties up to a depth of about 300 μm. The nanoindentation results for the 3-pass UITed sample revealed an increase of about 53, 45, and 220% in its nanohardness, H/E_r, and H³/E_r² indices, respectively. The stylus profilometry results showed that performing the UIT removed the L-PBF-related features/defects and offered a smooth surface. The roughness average (R_a) and the skewness (R_sk) of the 3-pass UITed sample were found to be lower than those of the L-PBFed sample by 95 and 223%, respectively. Applying the UIT also enhanced the material ratio, where the maximum load-bearing capacity (~ 100%) in as-L-PBFed (as-built) and 3-pass UITed samples was obtained at 60- and 10-µm depths, respectively. The tribological investigations showed that applying the UIT resulted in a significant reduction of wear rate and average coefficient of friction (COF) of CP-Ti. For instance, under the normal pressures of 0.05 and 0.2 MPa, the wear rate and COF of the 3-pass UITed sample were lower than those of the L-PBFed sample by 65 and 58%, and 20 and 17%, respectively.

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通过超声波冲击处理改善 L-PBF 加工商业纯钛的表面机械和摩擦学特性

采用多通道超声冲击处理（UIT）改变了激光粉末床熔融（L-PBF）法生产的商用纯钛（CP-Ti）试样近表面区域的微观结构，并改善了其机械和摩擦学特性。UIT 显著细化了与 L-PBF 工艺相关的针状马氏体（α′-M），并产生了均匀致密的表面微观结构，其中经过 1、3 和 5 次 UIT 处理的样品的孔隙率分别降低了 43%、60% 和 67%。经过 UIT 处理的样品的近表面机械性能提高了约 300 μm。经过 3 次 UIT 处理的样品的纳米压痕结果显示，其纳米硬度、H/Er 和 H3/Er2 指数分别提高了约 53%、45% 和 220%。测针轮廓测量结果表明，进行 UIT 可去除与 L-PBF 相关的特征/缺陷，并提供光滑的表面。经过 3 次 UIT 处理的样品的平均粗糙度 (Ra) 和偏斜度 (Rsk) 分别比经过 L-PBF 处理的样品低 95% 和 223%。应用 UIT 还提高了材料比率，在 60 微米和 10 微米深度处，L-PBFed（原样）和 3-pass UIT 样品分别获得了最大承载能力（约 100%）。摩擦学研究表明，使用 UIT 能显著降低 CP-Ti 的磨损率和平均摩擦系数（COF）。例如，在 0.05 和 0.2 兆帕的正常压力下，3 道 UIT 试样的磨损率和 COF 分别比 L-PBF 试样低 65% 和 58%，以及 20% 和 17%。

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来源期刊

Acta Metallurgica Sinica-English Letters METALLURGY & METALLURGICAL ENGINEERING-

CiteScore

6.60

自引率

14.30%

发文量

122

审稿时长

2 months

期刊介绍： This international journal presents compact reports of significant, original and timely research reflecting progress in metallurgy, materials science and engineering, including materials physics, physical metallurgy, and process metallurgy.