焊后热处理对7A04铝合金水下搅拌摩擦焊接接头组织性能的影响

对7A04铝合金板进行水下搅拌摩擦焊接(Submerged Friction Stir Welding,SFSW),并对焊接接头进行焊后热处理(Post Weld Heat Treatments,PWHT),研究焊后热处理对接头组织性能的影响。结果表明:焊后热处理接头呈现出弥散分布的细小析出相形貌,明显优于SFSW接头呈现出的少量析出相分散分布的特征。与SFSW接头相比,焊后热处理明显改善接头的力学性能。接头焊核区的平均硬度值提高了39.7HV,抗拉强度提高了67MPa,达到母材抗拉强度的96.1%,接头的应变硬化能力增强,拉伸断口呈现微孔聚合和解理混合断裂特征。     

厚板铝合金搅拌摩擦焊接头的冲击性能

采用搅拌摩擦焊对厚度为30 mm的2A12铝合金板材进行对焊连接,分析了接头不同厚度处的微观组织与冲击性能。结果表明:随着热输入量的减少,接头上层的晶粒相比于下层出现了粗化现象,导致接头上层区域的冲击韧性低于下层。焊核区晶粒最为细小,热机影响区次之,热影响区晶粒最为粗大;焊核区的冲击韧性高于热影响区,热机影响区由于存在微型裂纹,所以冲击韧性最低。焊核区上层的晶粒尺寸小于热机影响区下层的晶粒尺寸,但焊核区上层的冲击韧性低于热机影响区下层的冲击韧性,这是由于焊核区所含的Al₂CuMg脆性第二相的数量较多。焊接接头冲击韧性的变化不仅与焊缝不同区域的微观组织变化有关,还与该区域的第二相数量有关。     

铝合金搅拌摩擦焊研究现状及应用

搅拌摩擦焊是由英国焊接研究所发明的一种固相连接技术，可以对熔化焊接性差的铝合金进行可靠的连接，又具有诸多优点。介绍了搅拌摩擦焊工艺过程，分析了搅拌摩擦焊技术目前存在的优缺点，综述了铝合金搅拌摩擦焊的国内外研究现状和应用情况，指出搅拌摩擦焊为现代铝合金制造业提供了新的连接方法。     

6061铝合金无倾角搅拌摩擦焊工艺及性能

目的 为了适应空间曲面构件的搅拌摩擦焊,开展6061铝合金无倾角搅拌摩擦焊工艺及性能的研究。方法 采用无倾角搅拌摩擦焊用的搅拌头,对5 mm厚6061-T6铝合金板材进行试验,研究焊缝成形及接头力学性能,并分析接头组织特征。结果 零倾角搅拌摩擦焊接头从组织上可区分为5个不同区域：焊核区(WNZ)、热力影响区(TMAZ)、热影响区(HAZ)、轴肩影响区(SAZ)和母材(BM);随着搅拌头转速增加,焊缝宽度和焊核尺寸均先变大后变小;随焊接速度增加,焊缝宽度和焊核尺寸均逐渐变小;当焊接速度固定时,随搅拌头转速增加,接头拉伸强度先增加后减小;当搅拌头转速固定时,随焊接速度增加,接头拉伸强度逐渐增大。结论 采用无倾角搅拌摩擦焊接方法,能够实现对5 mm厚6061-T6铝合金板材的有效焊接。     

异种铝合金搅拌摩擦焊材料流动行为研究

采用异种铝合金交替排列的方法,研究了搅拌摩擦焊接过程中材料的变形和流动行为。结果表明:采用垂直焊缝交替排列的焊缝表面形成了两套弧纹,其中粗大弧纹是由于在焊接方向上两种铝合金交替排列而产生的周期性变化所致;受焊速和转速的影响,材料在前进侧流动剧烈且混合均匀,而后退侧因材料流动较弱仍与母材保持连续分布状态;由于材料塑性变形程度的差异,在轴肩影响区、搅拌针影响区和母材之间形成了明显的分界面。     

焊后时效对7046铝合金搅拌摩擦焊接头力学性能的影响

对厚度为3.5mm的7046铝合金挤压板材进行搅拌摩擦焊接并对焊接接头进行人工时效,研究了焊后时效对接头力学性能的影响.结果 表明,焊接接头时效前的硬度分布大致呈"W"形,抗拉强度为406.5 MPa,焊接系数为0.8,拉伸时在后退侧热影响区与热机影响区的过渡位置出现断裂,此处的硬度值最低,断裂面上有大量的韧窝;进行1...     

铝合金搅拌摩擦焊接头隧道型缺陷研究

焊接热输入不足导致铝合金搅拌摩擦焊接头中常出现隧道型缺陷，本文通过产热分析发现：选择与被焊材料摩擦系数斗较大的材料作为搅拌头制造材料；在圆柱体搅拌头的指头上制造螺纹提高焊接产热；提高旋转速度或者降低焊接速度来提高焊接线能量；减小搅拌指头半径r1是改善和消除隧道型缺陷的4种有效途径。     

超声冲击对铝合金搅拌摩擦焊接头组织及性能的影响

目的分析超声冲击对铝合金搅拌摩擦焊成形后接头的组织及耐蚀性的作用效果。方法采用超声冲击设备对2A12铝合金搅拌摩擦焊接头表面进行超声冲击处理,并对超声冲击前后接头的显微组织、显微硬度以及耐腐蚀性能进行了分析。结果经过超声冲击处理后的铝合金接头上表面会产生一层塑性变形层,并且塑性层内位错密度增大,使表层金属得到一定程度的加工硬化,促使冲击后接头各区域的表面硬度明显提高,冲击后接头热机械影响区和热影响区硬度提高达60%以上;腐蚀浸泡试验发现,超声冲击后接头的点腐蚀程度较超声冲击前明显减缓,腐蚀速率约是冲击前的1/2。结论超声冲击有效改善了铝合金搅拌摩擦焊接头区域材料过时效的软化现象,并且有效改善了接头的抗腐蚀性能。     

5083铝合金搅拌摩擦焊搭接接头研究

采用搅拌摩擦焊方法对5083铝合金进行搭接实验。用万能试验机对接头进行拉剪试验,对其断口利用SEM电镜进行观察和分析,并使用光学显微镜对其接头横截面进行组织观察。结果表明:即使搅拌针长度短于上层铝板的厚度,上、下层铝板在搅拌针作用的区域,晶粒都发生了一定细化,其尺寸都小于母材。而且焊缝横截面的显微硬度分布也显示出两板在搅拌针作用区域的硬度均与母材相当。在拉剪试验时,界面结合处没有出现断裂现象,断裂位置均在上层铝板前进侧的热影响区。接头强度系数最高可达80%,接头的断裂形式为韧性断裂。     

7050高强铝合金搅拌摩擦焊典型宏观缺陷试验研究

目的 研究7050铝合金搅拌摩擦焊接头中隧道缺陷及未焊透缺陷的行程规律及其对接头性能的影响。方法 采用预制间隙、改变搅拌针长度等方法获得了搅拌摩擦焊隧道缺陷及未焊透缺陷,通过金相分析、力学性能测试对缺陷及接头性能进行了分析。结果 相比隧道缺陷,根部未焊透缺陷对接头性能的影响更大,压入量对隧道、未焊透缺陷有重要影响,板厚5 mm,搅拌针长度小于4.8 mm时,未焊透缺陷对接头性能将产生显著影响。结论 应严格控制搅拌针长度及压入量,避免根部未焊透缺陷对接头性能的影响。     

Friction stir welding of high-strength aerospace aluminum alloy and application in rocket tank manufacturing

Friction stir welding (FSW) has been widely adopted in aerospace industry for fabricating high-strength aluminum alloy structures, such as large volume fuel tanks, due to its exceptional advantages including low distortion, less defects and high mechanical properties of the joint. This article systematically reviews the key technical issues in producing large capacity aluminum alloy fuel tanks by using FSW, including tool design, FSW process optimization, nondestructive testing (NDT) techniques and defect repairing techniques, etc. To fulfill the requirements of Chinese aerospace industry, constant-force FSW, retractable tool FSW, lock joint FSW, on-line NDT and solid-state equal-strength FSW techniques, as well as a complete set of aerospace aluminum FSW equipment, have been successfully developed. All these techniques have been engineered and validated in rocket tanks, which enormously improved the fabrication ability of Chinese aerospace industry.     

铝合金搅拌摩擦焊超声检测研究进展EI北大核心CSCD

铝合金搅拌摩擦焊(friction stir welding, FSW)焊接参数选择不当将会产生隧道孔、未焊透(lack of penetration, LOP)和吻接等取向复杂、细微紧贴的缺陷。首先,本文简述了FSW焊缝与典型缺陷特征,总结了超声检测时面临纵向分辨力低、缺陷表征不完整、材料与缺陷声阻抗接近和灵敏度不足等难点。随后,从常规超声、超声衍射时差法(time-of-flight diffraction, TOFD)、相控阵超声检测技术和其他超声检测技术等方面综述了现有的铝合金FSW超声检测研究工作。最后,结合超声信号处理方法和机器学习方法对研究前景进行展望:可以通过分析和提取信号特征,进一步提升超声检测分辨力和信噪比,并实现取向复杂缺陷和细微紧贴缺陷的精准辨识与定量。     

镁合金搅拌摩擦焊接工艺参数优化

为了优化镁合金搅拌摩擦焊接工艺参数,对5 mm厚镁合金AZ31B板材的搅拌摩擦焊接技术进行了试验研究,利用SN比实验设计,对镁合金AZ31B搅拌摩擦焊接工艺参数进行了方差分析,优化了搅拌头的材料、结构,最终确定搅拌头的材料为W6Mo5Cr4V2,结构为凹面圆台形.轴肩尺寸为12 mm.探针的根部直径为5.5 mm,端部直径为2.5 mm,长度为4.7 mm.获得镁合金AZ31B搅拌摩擦焊的工艺参数显著性顺序为旋转速度、横向速度和压力;确定了镁合金AZ31B搅拌摩擦焊的最优工艺参数为1500 r/min、47.5 mm/min、3kN.     

基于热力耦合模型铝合金搅拌摩擦焊接顺序优化仿真分析

基于所建立的搅拌摩擦焊接过程热输入模型和热力耦合有限元分析模型,对带圆孔铝合金板的搅拌摩擦焊接顺序进行了有限元研究,并得到了焊接过程中不同焊接方案下的温度、瞬态应力变化曲线以及焊后残余变形。通过综合比较可以看出,从两边向中间焊的方案2优于从中间向两边焊的方案1和从左向右的顺序焊接的方案3。此外,有限元模型求解结果和实验测量数据具有相当好的吻合。     

Friction stir welding characteristics of different heat-treated-state 2219 aluminum alloy plates

Friction stir welding (FSW) of 2219-O and 2219-T6 aluminum alloys was performed to investigate the effects of the base material conditions on the FSW characteristics. The experimental results indicated that the base material condition has a significant effect on weld morphologies, weld defects, and mechanical properties of joints. In the 2219-O welds, no discernible interface exists between the stir zone (SZ) and the thermal-mechanically affected zone (TMAZ), and weld defects are liable to form in the lower part of the weld. In the 2219-T6 welds, there is visible interface between the SZ and the TMAZ, and a weld nugget with an “onion ring”-like morphology clearly exists. The defects are liable to form in the upper part of the weld. The strength efficiency of 2219-O joints is 100%, while that of 2219-T6 joints is only up to 82%. In addition, the two types of joints have different fracture location characteristics.     

A356Al/TiB2颗粒增强铝基复合材料的搅拌摩擦焊

采用纯机械化的固相连接技术--搅拌摩擦焊成功地焊接了应用原位反应合成法制造的铸态A356Al/6.5%TiB2(体积分数)颗粒增强铝基复合材料,与铝合金相比,铝基复合材料搅拌摩擦焊的焊缝质量对焊接参数更为敏感.该连接方法在较低温度下实现铝基复合材料的焊接,避免了基体铝合金与增强相之间的化学反应,同时在搅拌头机械搅拌、挤压和摩擦热的共同作用下,焊缝区基体材料的晶粒和增强相被破碎并形成再结晶晶核,细化了组织结构,增强相分布也更加弥散.焊缝区的硬度值波动范围很小,抗拉强度比母材增加约20%.研究表明,搅拌摩擦焊用于连接颗粒增强铝基复合材料具有明显的优势.     

热处理对6005A铝合金激光焊接头组织和性能的影响

高速列车车体轻量化制造的迫切需求,使得铝合金结构在车体制造中得到广泛应用,而铝合金焊接也成为高铁车体制造的关键工艺.本文采用激光填丝焊方法焊接6005A-T6铝合金,并对焊接接头进行了固溶/时效热处理.利用扫描电镜、XRD能谱分析及拉伸实验,对焊后热处理的焊接接头组织及性能进行研究.研究发现,与母材相比,由于焊接接头中...     

Friction stir welding of PM2000 ODS alloy

Abstract

Friction stir welding has been used to join sheets of a ferritic, oxide dispersion strengthened alloy, PM2000. A stepped spiral probe, polycrystalline cubic boron nitride tool, with a shoulder diameter of 25 mm, was used to weld 4 mm thick plate in a butt joint configuration. The thermomechanically affected zone underwent dynamic recrystallisation during welding; the resultant microstructure consisted of equiaxed ferritic grains containing a dispersion of yttrium aluminium oxides. Microindentation measurements revealed a significant reduction in hardness within the weld zone, when compared to the parent material. The welding process induced an overall coarsening of the yttrium aluminium oxide particles and depletion in their number density. However, the precipitation of secondary phase particles, likely to be oxides, which took place during the welding process, is indicative that an element of mechanical alloying occurs during the welding process. Annealing the welds for 1 h at 1380°C produced a massive recrystallised grain structure in the weld zone and a uniform hardness across the parent and weld was achieved. Transmission electron microscopy showed that, subsequent to annealing, particles were coarser in the weld zone (33 nm mean diameter) than in the parent alloy (24 nm mean diameter). However, electron diffraction and energy dispersive X-ray spectroscopy confirm that the dominant oxide phase, YAlO₃ perovskite (YAP), was the same in both regions. Oxide particle size and number densities were not uniform throughout the weld. Focused ion beam prepared surfaces revealed particles within the size range of 50–600 nm diameter in material beneath the tool shoulder/workpiece contact area; the average size of dispersoids in this region was 130 nm.