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通过激光定向能量沉积原位制备TiC/Ti基复合材料

In Situ Fabrication of TiC/Ti-Matrix Composites by Laser Directed Energy Deposition.

作者信息

Mihai Sabin, Baciu Florin, Radu Robert, Chioibasu Diana, Popescu Andrei C

机构信息

Center for Advanced Laser Technologies (CETAL), National Institute for Laser, Plasma and Radiation Physics (INFLPR), 077125 Magurele, Romania.

Faculty of Industrial Engineering and Robotics, National University of Science and Technology Politehnica Bucharest, 060042 Bucharest, Romania.

出版信息

Materials (Basel). 2024 Aug 29;17(17):4284. doi: 10.3390/ma17174284.

DOI:10.3390/ma17174284
PMID:39274674
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11396267/
Abstract

In this study, crack-free TiC/Ti composites with TiC content ranging from 0 to 15 wt.% were successfully fabricated using Direct Energy Deposition with a dual-feeder system that concomitantly delivered different amounts of both constituents into a high-power laser beam. The samples were investigated to evaluate the morphologies and distribution behavior of TiC. The microhardness values of the samples obtained under optimal processing conditions increased from 192 ± 5.3 HV (pure Ti) to 300 ± 14.2 HV (Ti + wt.% 15 TiC). Also, TiC has a significant impact on the Ti matrix, increasing the strength of TMCs up to 725 ± 5.4 MPa, while the elongation drastically decreased to 0.62 ± 0.04%. The wear rate is not proportionally affected by the rise content of TiC reinforcement; the hypoeutectic region of TMCs exhibited a wear rate of 2.45 mm/N·m (Ti + wt.% 3 TiC) and a friction coefficient of 0.48 compared to the ones from the hypereutectic region, which measured a wear rate of 3.02 mm/N·m (Ti + wt.% 15 TiC) and a friction coefficient of 0.63. The improved values of mechanical properties in the case of TMCs as compared to pure Ti are provided due to the solid solution strengthening of carbon and the fine grain strengthening. This work outlines a method for changing TiC morphologies to improve the hardness and tensile strength of TMCs fabricated starting from micro-scale powder.

摘要

在本研究中,采用双送粉器系统的直接能量沉积法成功制备了TiC含量为0至15 wt.%的无裂纹TiC/Ti复合材料,该系统将两种成分的不同量同时输送到高功率激光束中。对样品进行了研究,以评估TiC的形态和分布行为。在最佳加工条件下获得的样品的显微硬度值从192±5.3 HV(纯Ti)增加到300±14.2 HV(Ti + 15 wt.% TiC)。此外,TiC对Ti基体有显著影响,将TMCs的强度提高到725±5.4 MPa,而伸长率急剧下降到0.62±0.04%。磨损率不受TiC增强相含量增加的成比例影响;TMCs的亚共晶区的磨损率为2.45 mm/N·m(Ti + 3 wt.% TiC),摩擦系数为0.48,相比之下,过共晶区的磨损率为3.02 mm/N·m(Ti + 15 wt.% TiC),摩擦系数为0.63。与纯Ti相比,TMCs的力学性能得到改善是由于碳的固溶强化和细晶强化。这项工作概述了一种改变TiC形态以提高从微米级粉末制备的TMCs的硬度和拉伸强度的方法。

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