A Functionally Gradient NiTi Shape-Memory Alloy Fabricated by Selective Laser Melting

IF 1 Q4 ENGINEERING, MANUFACTURING
Kun Li, J. Zhan, Ruijin Ma, Yingzhi Ren, Jinxin Lin
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引用次数: 0

Abstract

The near-equiatomic NiTi alloy has a shape memory function, but the simple forming structure limits its application. Selective laser melting is a promising way to manufacture functionally complex structures due to its layer-wise production advantage, which could broaden the applications of NiTi alloy in the engineering fields. This work explored a novel method of controlling the repetition of laser remelting to manufacture NiTi alloys with multiple phase-transformation temperatures via selective laser melting (SLM). The results demonstrates that the remelting strategy not only increases the ultimate tensile strength and elongation of the SLMed NiTi alloy, but also increases the Ms above room temperature. The increase in laser power increases the temperature at which martensite starts (Ms) to transformation in the range higher room temperature (25°C), thus increasing the critical stress of martensitic detwinning in the final sample. Through the optimized repetitive laser remelting strategy with different laser powers on specific areas of the sample, a functionally gradient NiTi build is successfully obtained. This study suggests SLM embedded with laser remelting is a potential method to realize 4D printing for NiTi alloys.
选择性激光熔化制备功能梯度NiTi形状记忆合金
近等原子NiTi合金具有形状记忆功能,但成形结构简单,限制了其应用。选择性激光熔化具有分层制造的优势,是一种很有前途的制造功能复杂结构的方法,可以拓宽NiTi合金在工程领域的应用。本工作探索了一种控制激光重熔重复的新方法,通过选择性激光熔化(SLM)来制造具有多种相变温度的NiTi合金。结果表明,重熔策略不仅提高了SLMed NiTi合金的极限抗拉强度和延伸率,而且提高了室温以上的Ms。激光功率的增加提高了马氏体在较高室温(25℃)范围内开始转变的温度(Ms),从而增加了最终样品中马氏体失孪的临界应力。通过优化的重复激光重熔策略,在不同的激光功率下对样品的特定区域进行重熔,成功地获得了功能梯度的NiTi构建。该研究表明,激光重熔嵌入SLM是实现NiTi合金4D打印的一种有潜力的方法。
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来源期刊
Journal of Micro and Nano-Manufacturing
Journal of Micro and Nano-Manufacturing ENGINEERING, MANUFACTURING-
CiteScore
2.70
自引率
0.00%
发文量
12
期刊介绍: The Journal of Micro and Nano-Manufacturing provides a forum for the rapid dissemination of original theoretical and applied research in the areas of micro- and nano-manufacturing that are related to process innovation, accuracy, and precision, throughput enhancement, material utilization, compact equipment development, environmental and life-cycle analysis, and predictive modeling of manufacturing processes with feature sizes less than one hundred micrometers. Papers addressing special needs in emerging areas, such as biomedical devices, drug manufacturing, water and energy, are also encouraged. Areas of interest including, but not limited to: Unit micro- and nano-manufacturing processes; Hybrid manufacturing processes combining bottom-up and top-down processes; Hybrid manufacturing processes utilizing various energy sources (optical, mechanical, electrical, solar, etc.) to achieve multi-scale features and resolution; High-throughput micro- and nano-manufacturing processes; Equipment development; Predictive modeling and simulation of materials and/or systems enabling point-of-need or scaled-up micro- and nano-manufacturing; Metrology at the micro- and nano-scales over large areas; Sensors and sensor integration; Design algorithms for multi-scale manufacturing; Life cycle analysis; Logistics and material handling related to micro- and nano-manufacturing.
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