V. V. Rubanik, D. Bahrets, V. I. Urban, В. В. Рубаник, Д. А. Багрец, В. И. Урбан
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引用次数: 0
Abstract
The paper presents the results of research on morphology, elemental composition, microhardness, corrosion properties of the surface layer of TiNi alloy subjected to ion-plasma (vacuum-arc method) deposition of TiN coating and ultrasonic treatment (UT) with different number of passes (n). The SEM method showed that ultrasonic treatment provides a significant reduction in the amount of the droplet phase on the TiN coating surface. The surface discontinuity of TiN coating at local points was observed with an increase in the number of passes during ultrasonic treatment. The effect of combined processing methods on the microhardness of TiNi sample was studied. It was shown that the synergistic effect can be observed for two hardening methods. The combined strengthening method increased the microhardness of TiNi alloy (1.6 GPa in the as-received state): due to the deposition of a TiN coating – up to 10.9 GPa, due to subsequently ultrasonic treatment – up to 14.5–18.4 GPa depending on the number of passes. For UT + TiN scheme, it was shown that the open circuit potential Ecorr was about –250 mV which is practically independent of the number of passes and determined by the potential value of TiN coating. For TiN + UT scheme, it was found that with an increase in the number of passes, the value of Ecorr shifts towards more negative values approaching the open circuit potential value of the TiNi sample in the as-received state (–350 mV). The analysis of Scanning Vibrating Electrode Technique (SVET) results showed high electrochemical compatibility of substrate (TiNi) and coating (TiN) materials in a chloride environment with minimal current density fluctuations for the samples subjected to UT + TiN and TiN + UT (n = 1). The proposed method for TiNi alloy treatment according to TiN + UT scheme (n = 1) promotes an improvement of surface morphology and corrosion resistance.
本文介绍了对经过离子等离子体(真空电弧法)沉积 TiN 涂层和不同通过次数(n)超声处理(UT)的 TiNi 合金表面层的形貌、元素组成、显微硬度和腐蚀性能的研究结果。SEM 方法表明,超声波处理可显著减少 TiN 涂层表面的液滴相数量。随着超声波处理次数的增加,TiN 涂层表面局部出现了不连续现象。研究了组合处理方法对 TiNi 样品显微硬度的影响。结果表明,两种淬火方法可以产生协同效应。组合强化方法提高了钛镍合金的显微硬度(在接收状态下为 1.6 GPa):由于 TiN 涂层的沉积 - 高达 10.9 GPa,由于随后的超声波处理 - 高达 14.5-18.4 GPa(取决于通过的次数)。对于 UT + TiN 方案,开路电位 Ecorr 约为 -250 mV,实际上与通过次数无关,由 TiN 涂层的电位值决定。对于 TiN + UT 方案,研究发现,随着通过次数的增加,Ecorr 的值会向更负的方向移动,接近 TiNi 样品在接收状态下的开路电位值(-350 mV)。扫描振动电极技术(SVET)的分析结果表明,在氯化物环境中,UT + TiN 和 TiN + UT(n = 1)样品的基底(TiNi)和涂层(TiN)材料具有很高的电化学兼容性,电流密度波动极小。根据 TiN + UT 方案(n = 1)提出的 TiNi 合金处理方法促进了表面形态和耐腐蚀性的改善。