添加剂制备NiTiHf的高温氧化动力学

Hediyeh Dabbaghi, M. Nematollahi, K. S. Baghbaderani, Parisa Bayatimalayeri, M. Elahinia
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引用次数: 3

摘要

niti基高温形状记忆合金(htsma),如NiTiHf,由于其高强度和高功输出,以及提高转变温度(tt)的能力,已被广泛应用于各种应用中。近年来,增材制造技术(AM)已被广泛用于制造复杂的形状记忆合金部件,而无需任何重大修改或工具,并为定制其最终零件的微观结构和关键性能的制造和制造铺平了道路。NiTi合金的性能,如转变温度,可以显著改变由于氧化,这可能发生在制造过程中或后处理。本文对采用选择性激光熔化法制备的富ni NiTi20Hf形状记忆合金的氧化行为进行了研究。热重分析(TGA)用于评估在500、700和900℃的不同温度范围内氧化在空气中20小时的动力学行为。氧化后,通过x射线衍射(XRD)、扫描电子显微镜(SEM)和能量色散x射线能谱(EDS)对其微观结构和化学成分进行评价。研究了传统NiTi20Hf合金的等温氧化动力学,并与AM样品进行了对比。结果表明,氧化速率为两阶段,初始阶段氧化速率较高。随着氧化时间的增加,氧化速率逐渐降低。NiTiHf合金的氧化行为最初服从对数速率规律,随后服从抛物线速率规律。SEM结果表明,氧化膜形成了一层多层氧化膜,主要包括TiO2、NiTiO3和Hf氧化物。
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High-Temperature Oxidation Kinetics of Additively Manufactured NiTiHf
NiTi-based high-temperature shape memory alloys (HTSMAs) such as NiTiHf have been utilized in a broad range of applications due to their high strength and work output, as well as, their ability to increase the transformation temperatures (TTs). Recently, additive manufacturing techniques (AM) have been widely used to fabricate complex shape memory alloy components without any major modifications or tooling and has paved the way to tailor the manufacturing and fabrications of microstructure and critical properties of their final parts. NiTi alloys properties such as transformation temperatures can be significantly altered due to oxidation, which can occur during the manufacturing process or post-processing. In this work, the oxidation behavior of Ni-rich NiTi20Hf shape memory alloys, which was fabricated by the selective laser melting (SLM) method, is evaluated. Thermogravimetric analysis (TGA) is used to assess the kinetic behavior of the oxidation at different temperature ranges of 500, 700, and 900 C for 20 hours in the air. After oxidation, to evaluate the microstructure and chemical composition X-ray diffraction (XRD), scanning electron microscopy (SEM), and energy-dispersive X-ray spectroscopy (EDS) was conducted. The isothermal oxidation kinetics of conventional NiTi20Hf alloys were studied, and the results were compared to AM samples. Results show a two-stage oxidation rate at which oxidation increased with the high rate at the initial stage. As the oxidation time increased, the oxidation rate gradually decreased. The oxidation behavior of NiTiHf alloys initially obeyed logarithmic rate law and then followed by parabolic rate law. SEM results showed the formation of a multi-layered oxide scale, including TiO2, NiTiO3, and Hf oxide.
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