Laser microwelding of NiTi/PtIr alloys with laser beam offset

IF 6.1 2区 材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Tetsuya Oyamada, Kaiping Zhang, Y. Norman Zhou, Peng Peng
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Abstract

The NiTi and PtIr alloy joint has been employed in biomedical devices to combine the superelasticity of NiTi alloy with the X-ray visibility of PtIr alloy. Laser microwelding is usually used for the joints, but there is a risk of forming brittle intermetallic compounds (e.g., Ni3Ti, Ti2Ni, and Ti3Pt) in the fusion zone (FZ), which could deteriorate joint strength. In this study, laser beam offset (laser offset) was implemented for a butt joint of Ni-49.8 at.% Ti and Pt-10.0 at.% Ir alloy wires to control the intermetallic compound formation in the FZ. Welding with 300 μm laser offset on the NiTi side achieved 2.3 times higher joint breaking stress and 13.0 times higher joint breaking strain than welding without laser offset. The joint breaking stress and strain were enhanced from 221 MPa and 0.9 % to 502 MPa and 11.7 % by 300 μm laser offset on the NiTi side, respectively. In the absence of laser offset, the dissolution of Pt and Ir into the FZ facilitated the M3Ti (M = Ni, Pt, Ir) formation in the FZ, resulting in crack propagation within the M3Ti. In contrast, the 300 μm offset on the NiTi side inhibited the M3Ti formation by mitigating Pt and Ir dissolution into the FZ. Laser offset on the NiTi side can be an attractive option to enhance the strength and ductility of NiTi and PtIr butt joints.
带激光束偏移的镍钛/铂铱合金激光微焊接
镍钛和铂铱合金接头已被用于生物医学设备中,以结合镍钛合金的超弹性和铂铱合金的 X 射线可见性。接头通常采用激光微焊接,但存在在熔合区(FZ)形成脆性金属间化合物(如 Ni3Ti、Ti2Ni 和 Ti3Pt)的风险,这会降低接头强度。本研究对 Ni-49.8% Ti 和 Pt-10.0% Ir 合金焊丝的对接接头采用了激光束偏移(激光偏移)技术,以控制 FZ 中金属间化合物的形成。在镍钛侧使用 300 μm 激光偏移进行焊接时,接头断裂应力是未使用激光偏移焊接时的 2.3 倍,接头断裂应变是未使用激光偏移焊接时的 13.0 倍。在镍钛侧进行 300 μm 激光偏移焊接后,接头断裂应力和应变分别从 221 兆帕和 0.9% 提高到 502 兆帕和 11.7%。在没有激光偏移的情况下,铂和铁溶解到 FZ 中促进了 M3Ti(M = Ni、铂、铁)在 FZ 中的形成,导致裂纹在 M3Ti 中扩展。与此相反,镍钛侧 300 μm 的偏移可减轻铂和铁溶解到 FZ 中的程度,从而抑制 M3Ti 的形成。在镍钛侧进行激光偏移可以提高镍钛和铂铱对接接头的强度和延展性。
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来源期刊
Materials Science and Engineering: A
Materials Science and Engineering: A 工程技术-材料科学:综合
CiteScore
11.50
自引率
15.60%
发文量
1811
审稿时长
31 days
期刊介绍: Materials Science and Engineering A provides an international medium for the publication of theoretical and experimental studies related to the load-bearing capacity of materials as influenced by their basic properties, processing history, microstructure and operating environment. Appropriate submissions to Materials Science and Engineering A should include scientific and/or engineering factors which affect the microstructure - strength relationships of materials and report the changes to mechanical behavior.
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