Microstructure and properties of dissimilar materials Ti/Cu welding joint by arc welding

被引：0

作者：

Li J. ^{[1
,2
]}

Zhou P. ^{[1
]}

Hui Y.-Y. ^{[1
]}

机构：

[1] School of Aeronautical Materials Engineering, Xi'an Aeronautical Polytechnic Institute, Xi'an

[2] State Key Laboratory of Advanced Processing and Recycling of Nonferrous Metals, Lanzhou University of Technology, Lanzhou

来源：

Zhongguo Youse Jinshu Xuebao/Chinese Journal of Nonferrous Metals | 2021年 / 31卷 / 09期

关键词：

Arc welding; Intermetallic compounds; Titanium-copper welding;

D O I：

10.11817/j.ysxb.1004.0609.2021-37856

中图分类号：

学科分类号：

摘要：

In order to promote the wide application of Ti/Cu dissimilar Metal welding structure, dissimilar metals of TA2 titanium and T2 copper were joined with butt joint by conventional argon tungsten-arc welding. The interfacial microstructures of the joints were analyzed by scanning electron microscopy(SEM), energy dispersive spectroscopy(EDS) and X-ray diffractometry(XRD). The results show that an intermetallic compound with a thickness of about 50μm forms in the interface reaction layer of Ti/Cu welding joint. The intermetallic compound layer is composed of CuTi, Cu2Ti and Cu4Ti3. The rod-like CuTi is near the titanium side, the massive and dendriticas Cu2Ti distribute in the intermediate region of the interfacial reaction, and Cu4Ti3 distributes along the edge of the dendrite compound Cu2Ti. The dissolution and diffusion of alloying element Ti to weld metal are very few, and the formation of interface reaction layer compound of Ti-Cu welding joint is dominated by liquid phase diffusion reaction. The tensile strength of the welding joint is up to 171 MPa, and the joint fractures in the intermetallic compound layer adjacent to the titanium base material, and the fracture is a typical brittle cleavage fracture. © 2021, China Science Publishing & Media Ltd. All right reserved.

引用

页码：2419 / 2426

页数：7

共 19 条

[1] DAI J J, ZHU J Y, CHEN C Z, Et al., High temperature oxidation behavior and research status of modifications on improving high temperature oxidation resistance of titanium alloys and titanium aluminides: A review, Journal of Alloys and Compounds, 685, pp. 784-798, (2016)
[2] GUO Xue-yi, TIAN QING-hua, LIU Yong, Et al., Progress in research and application of non-ferrous metal resources recycling, The Chinese Journal of Nonferrous Metals, 29, 9, pp. 1859-1901, (2019)
[3] FENG Qiu-yuan, TONG Xue-wen, WANG Jian, Et al., Status quo and development tendency on the research of low cost titanium alloy, Materials Reports, 31, 9, pp. 128-134, (2017)
[4] LI Zhou, XIAO Zhu, JIANG Yan-bin, Et al., Composition design, phase transition and fabrication of copper alloys with high strength and electrical conductivity, The Chinese Journal of Nonferrous Metals, 29, 9, pp. 2009-2049, (2019)
[5] LIU Xing-jun, WANG Cui-ping, GAN Shi-xi, Et al., Development of thermodynamic database for copper base alloy systems and its application in material design, The Chinese Journal of Nonferrous Metals, 21, 10, pp. 2511-2522, (2011)
[6] GUO Shun, ZHOU Qi, PENG Yong, Et al., Study on strengthening mechanism of Ti/Cu electron beam welding, Materials and Design, 121, pp. 51-60, (2017)
[7] AYDIN K, KAYA Y, KAHRAMAN N., Experimental study of diffusion welding/bonding of titanium to copper, Materials and Design, 37, pp. 356-368, (2012)
[8] PAUL H, SKUZA W, CHULIST R, Et al., The effect of interface morphology on the electro-mechanical properties of Ti/Cu clad composites produced by explosive welding, Metallurgical and Materials Transactions, 51, 2, pp. 750-766, (2020)
[9] FENG Zhen, CAO Rui, CHEN Jian-hong, Microstructure and properties of Ti6Al4V-T2 lap welded joints by cold metal transfer technology, Journal of Mechanical Engineering, 50, 16, pp. 135-139, (2014)
[10] PAUL H, CHULIST R, MISZCZYK M, Et al., Towards a better understanding of the phase transformations in explosively welded copper to titanium sheets, Materials Science and Engineering A, 784, (2020)

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