Microstructure and mechanical properties of Ti-Ti2AlNb interface

T. Niu, Bo Jiang, Ning Zhang, Yao-qi Wang
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Abstract

Diffusion bonding of Ti2AlNb alloy using pure titanium (Ti) foil as an interlayer was carried out on superplastic forming and diffusion bonding special equipment by gas pressure loading method. The microstructure of Ti-Ti2AlNb interface was observed using scanning electron microscope and energy-dispersive spectrometer while the mechanical properties of the joints were evaluated by shear test. The results show that the thickness of Ti foil interlayer has a great influence on the microstructure and shear strength of the interface diffusion region. When the thickness of the intermediate layer is thin (25 µm), Ti, aluminum (Al), and niobium (Nb) elements are fully diffused with uniform element distribution through the diffusion region. The diffusion layer region presents uniform, fine, and disordered lamellar α-Ti + β-Ti dual-phase structure with high shear strength. When the thickness of Ti foil interlayer is thick (50 µm), the distribution of Al elements is relatively uniform through the diffusion region due to its smaller radius and faster diffusion speed, and Ti and Nb elements present gradient distribution from the middle to both sides. The diffusion layer region presents a coarse and long strip shape α-Ti + β-Ti dual-phase structure in the middle part and a fine needle-like or irregular α-Ti + β-Ti dual-phase structure in both side parts, with slightly lower shear strength. Temperature has a great influence on the microstructure and mechanical properties of the diffusion bonding joints. The diffusion region presents a black α-Ti strip area in the middle part with the width of about 10 µm at lower temperature (910°C) with poorer property, due to the grain growth of the parent metal, the property is slightly poorer when the temperature is too high (960°C), and the optimal temperature is 930°C with a higher shear strength.
Ti-Ti2AlNb界面组织与力学性能
采用气压加载法在超塑性成形扩散连接专用设备上对纯钛(Ti)箔作为中间层的Ti2AlNb合金进行了扩散连接。采用扫描电镜和能谱仪观察了Ti-Ti2AlNb界面的微观组织,并通过剪切试验对接头的力学性能进行了评价。结果表明:Ti箔层厚度对界面扩散区的显微组织和抗剪强度有较大影响;当中间层厚度较薄(25µm)时,Ti、铝(Al)、铌(Nb)元素通过扩散区充分扩散,元素分布均匀。扩散层区呈现均匀、精细、无序的层状α-Ti + β-Ti双相结构,具有较高的剪切强度。当Ti箔夹层厚度较厚(50µm)时,由于其半径较小,扩散速度较快,Al元素在扩散区分布相对均匀,Ti和Nb元素呈现从中间到两侧的梯度分布。扩散层区域中部呈粗长条形α-Ti + β-Ti双相结构,两侧呈细针状或不规则α-Ti + β-Ti双相结构,抗剪强度略低。温度对扩散连接接头的组织和力学性能有很大的影响。在较低温度(910℃)下,扩散区中部呈现宽度约10µm的黑色α-Ti带状区域,性能较差,由于母材的晶粒生长,当温度过高(960℃)时,性能稍差,最佳温度为930℃,抗剪强度较高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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