异种材料及复合热源搅拌摩擦焊

在对接和搭接方式中,异种材料搅拌摩擦焊相较于同种材料分别具有一些额外的焊接参数,并且对搅拌头材料也有更苛刻的使用要求。总结近年来异种材料搅拌摩擦焊的研究现状,介绍异种材料搅拌摩擦焊过程中脆性金属间化合物的生成及其对焊接接头的力学性能产生的影响。从金属流动机理和数值模拟方面,研究金属间化合物的生成和成长规律,给出针对金属间化合物可能的解决方法。针对高熔点焊材,介绍复合热源搅拌摩擦焊技术、常用的辅助热源以及复合热源搅拌摩擦焊在异种材料搅拌摩擦焊方面的优点和研究的不足之处。     

异种材料搅拌摩擦焊接头特点与脆性本征研究

对镁合金与铝合金进行了搅拌摩擦焊连接试验.从接头金相形貌中可以看出,铝合金与镁合金的晶粒以河流状汇合的方式充分交织在一起,其排布具有明显的梯度特征.当这种混合的交织状态过渡到热机械影响区时可以发现,随着速度梯度的变化,混合的均匀程度明显减弱.接头附近存在大量的脆性金属间化合物,导致力学性能显著下降.从接头断口的扫描电镜形貌可以看出,单侧启裂的拉伸断口一侧出现少量韧窝带和大量的变形带断裂特征.     

异种材料的搅拌摩擦焊技术

进行了铝合金与工业纯铜、铝合金与低碳钢的搅拌摩擦焊接实验.实际焊接了对接接头、丁字接头、搭接接头,观察了焊接接头组织,测量了接头性能.结果表明,用搅拌摩擦焊方法代替熔化焊方法焊接异种材料,可以获得组织致密、无缺陷的接头,接头强度较高,且工艺适应性、结构适应性较好,焊接工艺参数、各组元在焊缝金属中的比例等对形成良好的焊缝有重要的影响.     

Joint characteristics and dissimilar materials joining of pure-Al/5083 by friction stir welding

Friction stir welding (FSW)^1,2, developed in 1991 by The Welding Institute, UK is a joining process which overthrew welding concepts which existed at the time; its application has been progressed not only for soft alloys including aluminium, but also, in recent years, for steel.³ Sato and others carried out friction stir welding on 1080-O and 5083-O materials and investigated variations in the hardness.⁴ Ten years or so have passed since the development of friction stir welding, the process has been globally investigated and widely employed in various sectors such as vehicles, ships and the aerospace industry. Furthermore, investigations have also been carried out into the manufacture of dissimilar metal joints. For example, Enomoto studied 2024/AC4C cast alloy and reportedly obtained satisfactory joints.⁵ Li and others have investigated 2024/6061 and reported that both alloys are distributed at the weld zone in a stratified and complex manner.⁶     

State of the art about dissimilar metal friction stir welding

Friction stir welding is a rather recent welding process (patented in 1991 by Thomas et al., ‘Improvements to friction welding’ UK patent application no. 9125978.8, US Patent 5460317, 1995) that has shown great potential for welding dissimilar materials even of different metallic nature, e.g. Al to steel, Mg to steel, Al to Ti, Mg to Ti, Al to Cu, Al to Mg. This review presents the specific microstructural features and mechanical properties, in particular tensile strength, of such welds. A focus will be on the material flow and welding defects, on the intermetallic compounds, on constitutional liquation, on particularities related to dissimilar lap welding and finally on process modifications to improve dissimilar friction stir weldability.     

Cu/Ti异种金属搅拌摩擦焊搭接接头组织与性能

文中采用搅拌摩擦焊法搭接T2工业紫铜和TA2纯钛,研究了搭接接头的宏观形貌和微观组织结构,并测试了接头力学性能.结果表明,当选用搅拌头旋转频率为800 r/min,焊接速度为40 mm/min的工艺参数配比时,可以获得焊缝表面成形良好,连接界面无缺陷的搭接接头.在焊核区,钛和铜以相间的条带结构形式相互混合、紧密连接在一起,形成了涡流状的钛铜双相金属混合区域,而且某些区域呈现出"机械互锁"的组织形貌.钛铜搭接接头抗剪切力可达到铜母材失效载荷的95%,断裂位置位于搭接接头铜板前进侧,为典型的韧性断裂.     

镁铝异种金属搅拌摩擦焊搭接接头组织与性能分析

采用搅拌摩擦焊技术对异种金属铝合金5083和镁合金AZ31进行了搭接焊试验.对接头的力学性能、组织形貌及断口形貌进行了观察和分析.结果表明,在铝板置于上层、搅拌针长度小于铝板板厚的情况下,使用合适的工艺参数,这两种轻合金可以获得抗剪性能良好、界面结合紧密、无缺陷的搭接接头,从而使镁板和铝板通过由一定金属间化合物组成的界面区过渡层形成了良好的连接;接头都断裂于界面结合处,铝侧是由塑性撕裂导致的"小坑"组成,而镁侧主要为河流状花样;在界面中心区出现了明显的硬度升高现象.     

铝/铜异种材料搅拌摩擦焊接工艺的优化

搅拌摩擦焊(FSW)是近几年发展较快的新型摩擦焊接技术.国内外研究较多的是铝合金及异种铝合金的搅拌摩擦焊接,但对铝/铜异种搅拌摩擦焊接的研究尚不多见.在此通过大量试验,分别在900-1500 rpm、20-50mm/min范围内调整搅拌旋转速度和焊接速度,优化焊缝的成形质量.结果表明,优化工艺参数可以实现铝/铜异种金属...     

镁铝异种合金搅拌摩擦焊综述

铝镁合金搅拌摩擦焊中峰值温度超过Al12Mg17和Al3Mg2形成的共晶温度,两种金属间化合物的形成不可避免。通过将镁合金置于前进侧、搅拌针偏向镁合金,采用液氮或水下搅拌摩擦焊,加入中间层过渡金属等方法可降低搅拌摩擦焊过程中的热输入,有效减少焊核区金属间化合物的数量。采用锥形螺纹搅拌针对接、配合直径约为3.5倍板厚的内凹型轴肩可提供适当的热输入,促进材料塑性流动,增加两种材料相互交融的程度,提高接头抗拉强度;超声辅助搅拌摩擦焊技术可破坏脆性界面层进而提高接头强度。     

铝/钢异质金属搅拌摩擦焊技术研究进展

铝/钢异质金属复合结构具有轻质节能、降低成本、可以满足不同的工作条件等特点,在航空航天、船舶制造等领域的应用日益受到重视。由于铝和钢的物理化学性质存在巨大差异,铝和钢的连接成为焊接领域的难点问题。搅拌摩擦焊作为一种固相连接方法,具有热输入低、高温停留时间短、焊接变形小等特点,对克服铝/钢异质金属性能差异带来的焊接困难具有优势,已成为铝/钢异质金属焊接的研究热点。综述了铝/钢异质金属搅拌摩擦焊国内外研究现状,主要涉及搅拌头材料选择与结构设计、焊缝成形、焊接工艺窗口、力学性能、接头冶金结合、连接机制以及外源辅助搅拌摩擦焊新技术,可以为铝/钢异质金属结构的轻量化设计提供新思路,最后对其发展趋势进行了展望。     

异种金属材料搅拌摩擦焊的研究现状及展望

对近年来国内外异种金属搅拌摩擦焊的研究现状进行了总结。重点对异种材料搅拌摩擦焊的特点、应用及其组织演化特征进行归纳和分析。异种材料连接结构具有两种材料综合的优异性能,随着异种材料连接结构应用前景的不断扩大,采用搅拌摩擦焊接技术的优势是生产效率高、焊接变形小、成本低、质量好等。但是,异种材料的搅拌摩擦焊技术存在一个突出的问题就是接头中存在金属间化合物,这会对其力学性能产生十分不利的影响。因此,在进行异种材料的搅拌摩擦焊时,对金属间化合物的形貌及分布状态的控制是获得优良焊接接头的关键所在。     

Numerical simulation of laser preheating of friction stir welding of dissimilar metals

Friction stir welding, FSW, of harder metal alloys is difficult to perform, like here dissimilar welding of titanium alloy to stainless steel in butt joint configuration. One major limitation is tool wear which can be reduced by preheating with a laser beam. A mathematical model to calculate the tool forces during FSW was developed further. The calculations show that the laser beam reduces forces at the pin and shoulder of the FSW-tool, accompanied by reduced heat generation through the tool. Within its operating limits, the process has low sensitivity on the lateral position of the leading laser beam. The model supports the understanding and optimisation of the complex interaction zone of forces and heat around the FSW-tool.     

钛合金/铝合金搅拌摩擦焊接头的显微组织

采用搅拌摩擦焊对TC1钛合金和LF6铝合金异种金属进行焊接,采用金相、扫描电镜和能谱观察分析焊接接头的组织.结果表明:搅拌摩擦焊接头中,钛合金母材与焊核的界面凸凹不平,边界处存在白亮颗粒,而铝合金母材与焊核的界面光滑、平整;焊核区铝合金基体上分布大小不等的颗粒,这种颗粒有两种类型,一种颗粒的尺寸较小、呈细长条状,另一种颗粒尺寸较大,整体呈暗灰色、边缘有少量发亮的条带.两种颗粒中均有Ti-Al金属间化合物存在;钛合金/铝合金异种材料焊接时,搅拌头的磨损很严重,在焊核和铝合金母材的边界存在搅拌头磨损后脱落的颗粒.     

Joining of dissimilar AZ31B magnesium alloy and SS400 mild steel by hybrid gas tungsten arc friction stir welding

The joining of dissimilar materials, magnesium alloy (AZ31B) and mild steel (SS400), was performed using a hybrid gas tungsten arc-friction stir welding (HGTAFSW) method that applied a preceding gas tungsten arc welding (GTAW) preheating heat source to a mild steel plate surface during friction stir welding (FSW). The mechanical and microstructural characteristics of the HGTAFS welds were evaluated and compared to those of FS welds to confirm the effect of the additional GTAW preheating heat source. The tensile strength of the HGTAFS welds was approximately 91% of that of the magnesium alloy base metal but higher than that of the FS welds. This was attributed to the enhanced material plastic flow and partial annealing effect in the magnesium alloy and mild steel materials by GTAW reheating of the mild steel side, which induced a significant increase in the elongation of the welds. The concentration profiles indicated that no intermetallic FeAl and FeAl₃ compounds had formed according to the phase diagram, which led to a decrease in joint strength. Overall, the use of HGTAFSW by applying a GTAW preheating heat source to a mild steelplate surface resulted in a mechanically sounder and metallurgically defect-free welds compared to FSW.     

铜/钢异种金属搅拌摩擦焊搭接工艺

采用SKD61模具钢搅拌头对2 mm厚铜/钢异种金属进行搅拌摩擦焊搭接,分析了搭接接头微观组织和力学性能. 结果表明,当搅拌针与钢母材直接接触时,随焊接过程的进行搅拌针不断磨损甚至发生断裂. 焊核区前进侧出现流线区域,在搭接界面结合处形成机械冶金结合. 显微硬度测试显示,铜侧焊核区硬度最高,在搭接界面处硬度分布呈中间高两边低的趋势,接头厚度方向搭接界面处硬度最高. 形成良好结合的搭接接头在拉剪试验中断裂于铜侧热影响区,拉伸断口存在大量韧窝,呈典型韧性断裂模式.     

铝合金搅拌摩擦焊异种焊接头的显微组织和力学性能

对8mm厚6082/5083铝合金进行了搅拌摩擦焊焊接,焊后通过金相分析、拉伸试验和断口形貌观察等方法研究了搅拌摩擦焊异种焊接头的显微组织和力学性能.研究结果表明:在旋转速度800 r/min、焊接速度120 mm/min工艺条件下,接头表面成形良好,内部无明显缺陷.焊核区是由细小的等轴晶组织构成;前进边和回转边的界面形态差异较为明显,前进边的组织形貌呈花纹状,由两种铝合金组织交互融合而成,但回转边组织形貌则呈曲线状,明显将两种组织分开.断口形貌分析显示,接头断裂模式为脆性断裂.     

异种材料搅拌摩擦焊接接头金相试样的制备技术

通过对搅拌摩擦焊接接头金相试样制备技术的经验总结，介绍了异种材料搅拌摩擦焊接接头金相试样制备过程中磨光、抛光和浸蚀等关键操作，提出在金相试样的制备过程中的注意事项和技术要点，对搅拌摩擦焊接接头的微观组织分析、工艺制定等具有一定的参考价值。     

高熔点材料的搅拌摩擦焊接技术

通过焊具设计、接头微观组织与性能、焊接温度场和残余应力、热源辅助的搅拌摩擦焊(FSW)几个方面,全面介绍了高熔点材料搅拌摩擦焊技术的研究现状.结果表明,合适的搅拌头材料为钨铼(W-Re)合金和多晶立方氮化硼(PCBN);采用合适的焊具设计和工艺参数,可以得到具有良好微观组织、高强度的FSW接头;在模拟搅拌摩擦焊温度场和接头残余应力时,应依据焊接过程实际进一步完善物理模型;引入辅助热源有利于高熔点材料焊缝成形并提高焊具使用寿命.     

Development of processing windows for friction stir spot welding of aluminium Al5052 /copper C27200 dissimilar materials

Friction stir spot welding technique was used to join dissimilar combinations of aluminium alloy (Al5052) with copper alloy (C27200) and friction stir spot welding windows such as tool rotational speed–dwell time and tool rotational speed–plunge depth diagrams for effective joining of these materials were developed. Using a central composite design model, empirical relations were developed to predict the changes in tensile shear failure load values and interface hardness of the joints with three process parameters such as tool rotational speed, plunge depth and dwell time. The adequacy of the developed model was verified using ANOVA analysis at 95% confidence level. Response surface methodology was used to optimize the developed model to maximize tensile strength and minimize interface hardness. A high tensile shear failure load value of 3850 N and low interface hardness value of HV 81 was observed for joints made under optimum conditions, and validation experiments confirmed the high predictability of the developed model with error less than 2%. The operating windows developed shall act as reference maps for future design engineers in choosing appropriate friction stir spot welding process parameter values to obtain good joints.     

异种铝合金摩擦焊接移动速度和旋转速度的优化(英文)

在摩擦焊接过程中的热效应导致的高模量使铝合金容易变形、强度降低。对船用异种铝合金进行了搅拌摩擦焊接。确定5052-0和6061-T6铝合金在焊接时移动速度和旋转速度的最优条件。得到铝合金最佳焊接条件为移动速度61mm/min和旋转速度1600r/min。