Ti和Fe连续驱动摩擦焊焊接界面宏观变形及微观形貌研究
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摘要
为了给钛/钢连续驱动摩擦焊制造提供理论支撑,采用钛和钢主体元素的纯钛和纯铁进行连续驱动摩擦焊试验,研究了焊接时间和摩擦压力对界面宏观变形和组织演变的影响规律。试验结果表明:随着摩擦压力的增大,界面宏观变形增大。随着焊接时间的增加,界面宏观变形变化不大。焊接界面两侧组织细化明显,Fe侧由细小的铁素体晶粒组成,Ti侧由细小的α晶粒组成。塑性层厚度随摩擦压力增加而增加,且近似为线性关系,焊接时间对塑性层厚度影响不大。
In order to provide theoretical support for continuous drive friction welding manufacturing of titanium and steel, the continuous drive friction welding test of pure titanium and pure iron which are the main element of titanium alloy and steel was carried out. The effects of welding time and friction pressure on the macroscopic deformation and the microstructure evolution of the interface were studied. The results show that with the increase of the friction pressure, the interface macroscopic deformation increases. With the increase of welding time, the change of interface macroscopic deformation is not obvious. The microstructure at two sides of the welding interface is refined. The microstructure in the Fe side is composed of fine ferrite and the microstructure in the Ti side is composed of fine α grains. With the increase of the friction pressure, the thickness of plastic layers increases and the relationship between the thickness of plastic layer and friction pressure is approximately linear relation. In addition, the effect of welding time on the thickness of plastic layers is not obvious.
In order to provide theoretical support for continuous drive friction welding manufacturing of titanium and steel, the continuous drive friction welding test of pure titanium and pure iron which are the main element of titanium alloy and steel was carried out. The effects of welding time and friction pressure on the macroscopic deformation and the microstructure evolution of the interface were studied. The results show that with the increase of the friction pressure, the interface macroscopic deformation increases. With the increase of welding time, the change of interface macroscopic deformation is not obvious. The microstructure at two sides of the welding interface is refined. The microstructure in the Fe side is composed of fine ferrite and the microstructure in the Ti side is composed of fine α grains. With the increase of the friction pressure, the thickness of plastic layers increases and the relationship between the thickness of plastic layer and friction pressure is approximately linear relation. In addition, the effect of welding time on the thickness of plastic layers is not obvious.
引文
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[6]李京龙,李洵,张昊,等.摩擦焊产热基础问题探讨[J].航空制造技术,2015,20(2):42-46.
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[9] Crossland B. Friction welding[J]. Contemporary Physics,1971,12(6):559-574.
[2] Wang T, Zhang B G, Chen C Q, et al. High strength electron beam welded titanium-stainless steel joint with V/Cu based composite filler metals[J].Vacuum,2013, 94:41-47.
[3] Dey H C, Ashfaq M, Bhaduri A K, et al. Joining of titanium to304L stainless steel by friction welding[J]. Journal of Materials Processing Technology,2009, 209:5862-5870.
[4] Li P, Li J L, Salman M, et al. Effect of friction time on mechanical and metallurgical properties of continuous drive friction welded Ti6Al4V/SUS321 joints[J]. Materials and Design, 2014, 56:649-656.
[5] Li X, Li J L, Liao Z X, et al. Microstructure evolution and mechanical properties of rotary friction welded TC4/SUS321 joints at various rotation speeds[J]. Materials and Design, 2016, 99:26-36.
[6]李京龙,李洵,张昊,等.摩擦焊产热基础问题探讨[J].航空制造技术,2015,20(2):42-46.
[7] Xiong J T, Li J L, Wei Y N, et al. An analytical model of steady-state continuous drive friction welding[J].Acta Materialia,2013, 61(5):1662-1675.
[8] Vill V I. Friction welding of metals[M]. American Welding Society, Reinhold Publish Co.,Ltd., 1962:27-33.
[9] Crossland B. Friction welding[J]. Contemporary Physics,1971,12(6):559-574.
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