Wire and arc additive manufacturing of 4043 Al alloy using a cold metal transfer method

Cold metal transfer plus pulse(C+P)arc was applied in the additive manufacturing of 4043 Al alloy parts.Parameters in the manufacturing of the parts were investigated.The properties and microstructure of the parts were also characterized.Experimental results showed that welding at a speed of 8 mm/s and a wire feeding speed of 4.0 m/min was suitable to manufacture thin-walled parts,and the reciprocating scanning method could be adopted to manufacture thick-walled parts.The thin-walled parts of the C+P mode had fewer pores than those of the cold metal transfer(CMT)mode.The thin-and thick-walled parts of the C+P mode showed maximum tensile strengths of 172 and 178 MPa,respectively.Hardness decreased at the interface and in the coarse dendrite and increased in the refined grain area.

Microstructure and mechanical properties of dissimilar joint between aluminum and aluminum-coated steel by cold metal transfer process

Two dissimilar materials, aluminum alloy and aluminum-coated steel, were joined by cold metal transfer process using AlSi5 filler wire. To this end, the steel was coated with Al-Si. The steel did not melt and aluminum was melt to form the joint during the process, it was actually cold metal transfer welding-brazing. The macrostructure, microstructure, alloy element distribution, and inter-metallic compounds were analyzed by optical microscopy, scanning electron microscopy, and energy dispersive spectroscopy. It was found that the Al-Si coating dissolved into the weld metal. The pre-existing thin Fe-Al- Si ternary inter-metallic compounds in the interface between the Ak-Si coating layer and base metal steel also partially dissolved into the weld zone, tending to reduce the thickness of inter-metallic compounds. Approximate 3 μm thick undissolved intermetallic compound was found at the interface after welding which could guarantee sound bonding strength in dissimilar materials joining. The sample was fractured at the fusion zone near the aluminum side in the tensile test. The ultimate tensile strength was about 156 MPa, and the fracture mode is ductile failure in nature according to its morphology.

Study on Relationship Between Arc Behavior and Joint Forming in Cold Metal Transfer Welding Technology with Polarity⁃Exchanging

Cold metal transfer with polarity⁃exchanging is a new integrated welding technology based on MIG.Due to the alternation of the positive and negative polarities of the wire,favorable control upon the deposition rate and the welding shape coefficient was obtained in order to meet the desired joint design,and the related controlling principles and joint characteristics were reported.Droplet transfer physical behavior exhibited strong dependability on the studied welding parameters,such as welding voltage,welding current,wire feeding speed,and polarity⁃exchanging.This welding technology provides a new way for the welding of body⁃in⁃white(BIW)thin sheet with special demands.Moreover,the typical quality defects of MIG were greatly improved.Our study provides important technical information from the perspective of industrial application of MIG and sheds light on the higher application level of MIG in BIW welding.

Cold metal transfer(CMT) technology-An overview

Cold Metal Transfer technology has revolutionized the welding of dissimilar metals and thicker materials by producing improved weld bead aesthetics with controlled metal deposition and low heat-input. In this study, the process, weld combinations, laser-CMT hybrid welding and applications of CMT welding are critically reviewed. Microstructure and other weld characteristics have been discussed at length for various base metal combinations. Particularly, the welding of aluminium and steel with better results has been possible with CMT Welding. The results reviewed in this article indicate that the CMT-Laser hybrid welding is more preferable to Laser or Laser hybrid welding. CMT welding has found applications in automobile industries, defence sectors and power plants as a method of additive manufacturing.

FEM modeling of softened base metal in narrow-gap joint by CMT+P MIX welding procedure

A required finite element method（FEM） model applicable for narrow gap CMT and CMT＋P MIX welding was established based on the interactions between arc,base metal and filler metal.A novel method of simplifying wire feeding pulses and heat input pulses was supposed under the conduction of equivalent input.The method together with composed double-ellipse heat sources was included in the model.The model was employed in the investigation of thermal cycling and the identification of the softened zone of AA7A52 base plates.Low-frequency behavior emerged in the form of low-cooling rate sects,which were not expected under experimental conditions.The softened zone including the quenched zone and averaging zone of the base plate was much wider internal the base plate than that close to the surfaces.The reliability of the predictions in thermal cycling was supported by infrared imaging test results of the thermal cycle process.

Cu对铝/钢CMT熔钎焊接头界面区组织的影响研究

采用冷金属过渡方法,以AlSi5焊丝为填充金属,在5052铝合金和镀锌钢板之间添加铜箔片进行搭接熔钎焊,使用扫描电子显微镜结合能谱分析和拉伸试验机对接头的界面区组织与性能进行研究。结果表明,未加入铜箔时,界面区组织主要由FeAl_(3)金属间化合物组成;铜箔的加入使得界面区组织中新生成了CuAl_(2)金属间化合物,同时改善了Zn在界面区的分布。Zn固溶于Al中,一定程度上抑制了Fe-Al金属间化合物产生。加入铜箔后的试样断裂位置发生改变,接头的承载能力与未加入铜箔的相近。

基于BAS算法优化的电弧增材制造焊道尺寸预测

目的为提高实际应用中电弧增材制造对工艺参数的选取效率及成形形貌的控制效果,建立高效且精准的成形尺寸预测模型,实现对焊道尺寸的合理预测。方法在单层单道CMT电弧增材制造实验的基础上,建立基于天牛须搜索算法(Beetle Antennae Search,BAS)优化BP神经网络的焊道尺寸预测模型,利用BAS算法实现对BP神经网络初始权值和阈值的优化,可以实现预测不同工艺参数(焊接速度、送丝速度、干伸长)下焊道的成形尺寸(熔宽、余高)。利用试验验证BAS-BP预测模型的性能,与现有模型进行对比,结果结果表明该模型具有较高精度的预测效果,能够有效映射工艺参数与焊道尺寸之间的非线性关系,印证了该模型具有良好的拟合和泛化能力,同时其对焊道熔宽和余高的预测误差分别不超过0.2、0.12 mm,预测平均误差率均不超过6%,相对于其他预测模型表现出较好的准确性和稳定性。结论BAS-BP神经网络预测模型的输出误差较小,网络训练收敛速度加快,避免了过拟合及欠拟合的风险,有效提高了预测模型的泛化能力和预测精度,可以实现一定工艺参数范围内的焊道尺寸预测,为后续电弧增材的实时预测及控制参数应用提供了技术支持。

基于工程应用的CW-GMAW熔滴过渡形态表征

综述了涉及工程应用的冷丝熔化极气体保护焊(Cold wire gas metal arc welding,CW-GMAW)熔滴过渡形态特征。结果表明,在大电流、强规范、富氩混合气体保护下,CW-GMAW工艺的熔滴过渡形态呈喷射过渡;当电流较小、电弧电压较低时,可能为滴状过渡,甚至在弧压很低时,呈现短路过渡形态。该工艺电弧发生偏向冷丝的位移,弧长变短甚至发生短路,与冷丝送进速率比增高及冷丝在电弧中产生大量金属蒸气时弧柱电阻下降有关。在具有富氩混合保护气体的相同工艺参数下,CWGMAW转变电流比GMAW降低了4%~7%。焊接工艺参数对CW-GMAW和GMAW工艺熔滴过渡形态的影响规律大致相近,但前者因涉及冷丝送进速率比和电极焊丝送进速度,以及它们的匹配等,使焊接电流的影响更为复杂。

4043铝合金电弧增材制造的组织及力学性能

为了研究4043铝合金电弧增材制造中工艺参数、组织与力学性能之间的相关规律,采用CMT电弧增材制造技术制备了4043铝合金薄壁件。通过金相显微镜、扫描电子显微镜、电子万能试验机等检测设备,对不同工艺参数(焊接速度和送丝速度)制备的制件内部组织与力学性能进行了研究。结果表明,WAAM4043铝合金薄壁件内部组织为α(Al)相和β(Al_(3.21)Si_(0.47))相。随着焊接线能量的增加,Al-Si共晶相会增多,晶界处的β相变得粗大、松散,晶粒也变得粗大。4043铝合金薄壁件的抗拉强度最高为153.7 MPa,伸长率最高为22.5%。拉伸性能在横向与竖向上呈各向异性。过大或过小的焊接线能量都不利于获得好的力学性能。

焊接模式对电弧增材制造316不锈钢组织及力学性能的影响

基于冷金属过渡、冷金属过渡-脉冲以及直流脉冲三种焊接模式,开展了316不锈钢单道多层薄壁试样的电弧增材制造,并对试样进行了组织与性能的对比分析.结果表明,三种模式下成形构件均无塌陷和宏观气孔现象,凝固组织以柱状树枝晶为主,并伴随有大量的二次枝晶、胞状晶,通过金相观察和背散射电子衍射技术发现,组织表现出强<001>//z织构,构件中段稳态区的平均枝晶间距随不同焊接模式下的热输入变化而变化:由小到大依次为CMT—CMT-P—DC-P.通过X射线衍射和扫描电镜-能谱分析确定基体组织为γ-Fe(Cr0.19Fe0.7Ni0.11),基体间网状组织为残余δ-Fe.CMT-P模式下的构件强度最高,屈服强度达237 MPa,抗拉强度达555 MPa,平均硬度值达209 HV0.3,DC-P模式构件的断后伸长率最高达52%.

CMT电弧增材制造铝合金传热传质与熔池行为数值模拟

为研究冷金属过渡(cold metal transition,CMT)电弧增材制造铝合金传热传质与熔池流动特性,基于Fluent软件建立了三维CMT电弧增材制造数值模型.模型中,采用动网格技术模拟焊丝竖直方向上的往复运动,利用流体体积法捕获气/液界面,焓-孔隙率法追踪固/液界面,并施加周期热量输入和阶段电弧力作用来等效电弧放电行为,研究分析了焊道成形传热传质过程与熔池动态行为.结果表明,焊道成形初期,熔池余高和坡度较大,形貌犹如半个球体,成形后期热量积累造成焊道余高后方较前方略小,而后端熔宽较前端略宽;单滴过渡周期内,焊丝机械回抽对熔池表面流动影响最为明显,液桥断裂产生较大反冲作用于熔池;熔池内部则是电磁力作为主导驱动力产生一股顺时针环流,环流随燃弧阶段周期切换而不断加强与减弱,并基本贯穿整个过渡周期,使得熔池内部热对流更加充分.模拟结果与试验结果显示吻合良好.

1561铝合金双丝冷金属过渡焊接工艺试验

针对1561铝合金的应用需求,开展1561铝合金双丝冷金属过渡焊接(Cold Metal Transfer Welding, CMT)工艺试验。对试验材料、装配要求、焊缝质量要求和作业要求进行论述,并从目视检测、渗透检测、断面宏观检验、常规力学性能、耐腐蚀性能和疲劳性能等方面对1561铝合金双丝CMT试验结果进行分析。试验结果表明,1561铝合金双丝CMT工艺性能优良,可满足技术指标要求。

车用薄镀锌板CMT搭接工艺特性

针对车用薄镀锌板材料,为了进一步降低冷金属过渡(cold metal transfer,CMT)时产生的飞溅,研究分析了薄镀锌板CMT搭接焊接工艺特性.采用Baumer HX 13工业级高速摄像机拍摄了CMT焊接熔滴过渡图像,利用NI PXI数据采集系统采集了CMT焊接电流电压信号.主要研究了短路前期阶段与短路后期阶段电流电压对CMT熔滴过渡的影响规律,同时分析了焊枪倾角对薄镀锌板CMT搭接焊接熔滴过渡行为的影响.结果表明,当CMT短路阶段电流小于基值阶段电流时,电信号波形未出现扰动现象,焊接过程稳定;当降低短路后期电流约5 A时,能够有效降低CMT搭接产生的飞溅;当焊枪与垂直平面呈30°夹角时,能够获得平稳的熔滴过渡,焊接飞溅最小,焊缝熔深最大,焊缝成形最佳.故短路阶段电流小于基值阶段电流且降低短路后期电流约5 A时,采用焊枪倾角30°的焊接工艺能够实现较小的焊接飞溅,为生产实践提供理论依据.

焊接方法对镍基合金耐晶间腐蚀性能的影响

为了研究双金属复合管中镍基合金堆焊层的耐腐蚀性能,分别采用钨极氩弧焊(GTAW)与冷金属过渡焊(CMT)两种焊接工艺在X65管线钢表面熔覆一层厚度为3 mm的625合金(Inconel 625)内衬层.通过双环电化学动电位再活化(DL-EPR)试验来评估通过两种工艺得到的堆焊层的耐晶间腐蚀性能,试验得出通过CMT得到的堆焊层的晶间腐蚀敏感度(DOS)值比GTAW堆焊层的DOS值低0.5%,这表明相比于传统的GTAW堆焊层,通过CMT工艺得到的堆焊层具备更优良的耐晶间腐蚀性能.此外,模拟服役工况的失重腐蚀试验被用来进一步评估堆焊层的耐腐蚀性能,腐蚀试验后的GTAW堆焊层与CMT堆焊层试样表面均出现了不同程度的腐蚀,其中GTAW堆焊层试样表面出现了大量富含Fe、S的腐蚀产物,而CMT堆焊层表面仅存在极少量的腐蚀产物.通过腐蚀前后试样的质量变化计算得到GTAW堆焊层的腐蚀失重速率为0.12 mm/a,而CMT堆焊层其腐蚀失重速率仅为0.01 mm/a.这进一步证明了相比于GTAW工艺采用CMT工艺得到的堆焊层耐晶间腐蚀性能更好.此外,在同一焊接工艺下,堆焊层的耐晶间腐蚀性能存在不均性,靠近熔合界面位置处的堆焊层中较高的Fe含量降低了堆焊层的耐晶间腐蚀性能.

焊丝成分对高氮钢CMT+P焊工艺性的影响

为提升高氮钢焊接质量和优化焊接工艺,研究焊丝氮、锰含量带来的焊接工艺稳定性。采用冷金属过渡加脉冲(Cold Metal Transfer plus Pulse,CMT+P)焊技术对5种高氮钢焊丝进行焊接试验,研究焊丝成分对电信号、熔滴过渡、飞溅率的影响。研究结果表明:氮含量的增加会引起电信号波动变大且分布离散,而锰含量的变化对电信号的影响较小,焊丝中氮含量对高氮钢CMT+P焊接稳定性影响大于锰含量的影响;随着氮含量的增加,熔滴过渡模式由一脉一滴转变为多脉一滴,熔滴形状不规律且尺寸变大,焊丝工艺性变差;当焊丝中氮、锰含量较小,分别为0.42%、7.19%时,焊接工艺稳定性较好;氮逸出、锰蒸发导致高氮钢熔滴剧烈爆炸产生大量飞溅,焊接飞溅率随着氮、锰含量的增加而不断增大。

TiB_(2)/6056复合材料的电弧增材制造工艺及组织分析

采用冷金属过渡(CMT)方法在6061铝合金板上进行TiB_(2)/6056丝材增材制造研究。以送丝速度、焊接速度为变量,对不同热输入下增材层的表面成形、微观组织进行了观察和分析。结果表明:增大热输入,有利于降低复合材料增材焊道的气孔率。当热输入在1.2~2.4 kJ/cm时,焊道成形良好,表面光滑,鱼鳞纹均匀。随着热输入的增大,焊道的熔宽和余高增加,增材层组织由树枝晶→胞状晶→等轴晶转变。增材焊道中细小的TiB_(2)颗粒大都呈聚集态分布在α-Al的晶间位置。

正负极性CMT铝焊丝熔滴体积增长量分析

为了定量研究铝焊丝在正负极性冷金属过渡时熔滴体积的变化情况,搭建了VP CMT熔滴过渡图像及电信号采集平台.利用数字图像处理技术,对拍摄得到的熔滴过渡图像进行处理,得到了仅包含焊丝、熔滴轮廓的二值图像.结合焊丝直径与熔滴径向尺寸之间的关系特征,将熔滴与焊丝之间“固-液”分界面的判定分为焊丝直径大于、等于、小于熔滴径向尺寸3种情况进行讨论,提出了判别熔滴与焊丝之间“固-液”分界面的具体方法.首先基于此方法得到了不同工艺参数下,铝焊丝在燃弧阶段不同时刻的瞬时熔滴体积.依据燃弧阶段末期与燃弧阶段初期的熔滴体积,计算得到了不同极性下的熔滴体积增长量.发现在相同的工艺参数下,焊丝极性接负(EN)阶段的熔滴体积增长量明显大于焊丝极性接正(EP)阶段.之后给出了燃弧阶段输入功与熔滴体积增长量之比(W/ΔV)参量,并定量对比了在不同的工艺参数下,EP和EN阶段的W/ΔV变化.结果表明,熔化相同体积的铝焊丝,EP阶段所需要的燃弧阶段输入功约为EN阶段的2.2倍.最后结合焊丝作为阴(阳)极时的产热以及电弧在EN阶段沿焊丝产生“上爬”现象对上述结果进行了解释.该研究为后续精确控制溶滴尺寸,进而控制焊缝成形提供了借鉴.

铝合金补焊工艺与疲劳性能的研究进展

铝合金具有氧化性强、热导率大和凝固收缩率大等特点,使用传统补焊工艺修复铝合金构件可能会使接头性能弱化,无法保证补焊修复质量。本文综述了搅拌摩擦焊、激光熔覆焊和冷金属过渡焊等新型修复技术的工艺特点及其在铝合金补焊领域的研究进展。针对铝合金结构补焊后疲劳性能下降问题,总结了疲劳破坏机理和工艺措施等方面的创新性研究成果,为铝合金补焊技术的理论研究和实际应用提供参考。

铝合金熔敷层数对添加Nb中间层钛/铝异种合金CMT-WAAM构件微观组织影响

针对采用基于冷金属过渡(CMT)技术所制备的添加Nb中间层钛/铝异种合金电弧增材制造(WAAM)试样,研究了铝合金熔敷沉积层数对试样微观组织的影响规律。结果表明:随着铝合金熔敷沉积层数由1层增加至5层,添加Nb中间层钛/铝异种合金试样中第1层铝合金熔敷沉积层发生重熔的次数逐渐增加,使得铝合金沉积层中所析出的Al3Nb金属间化合物数量有所减少,且尺寸也有所减小;随着铝合金熔敷沉积层数的增加,铝合金熔敷沉积层底部所析出的Al3Nb金属间化合物呈岛状-长条状-短棒状的分布特征;分别熔敷沉积1层、3层和5层铝合金时,添加Nb中间层钛/铝异种合金试样中铝合金熔敷沉积层与Nb中间层之间均会形成Al3Nb金属间化合物反应层,反应层的厚度分别为1.1~2.9μm, 1.3~3.6μm和1.4~3.6μm。

钛合金/铜-镍/不锈钢焊接接头的组织与性能

采用铜-镍复合填充金属进行了钛合金和不锈钢的冷金属过渡焊接,借助扫描电子显微镜、X射线衍射仪研究铜-镍复合填充金属对钛合金/不锈钢焊接接头微观组织和力学性能的影响.结果表明,添加铜-镍复合填充金属后得到了无焊接缺陷的钛合金/不锈钢焊接接头.接头中形成了硬度相对Ti-Fe,Ti-Cu金属间化合物较低的Ti-Ni金属间化合物,改善了钛合金/不锈钢焊接接头的拉伸性能.当焊接电流为182 A时,钛合金/不锈钢接头的拉剪强度最大为348 MPa.钛合金/不锈钢接头由不锈钢-焊缝金属界面、不锈钢-纯镍-钛合金界面、钛合金-焊缝金属界面和焊缝金属组成,接头中形成了Ti-Cu,Ti-Ni,Al-Cu-Ti和Al-Ni-Ti-Fe-Cu金属间化合物.随着焊接电流的增大,钛合金侧界面反应层的显微硬度逐渐增大,且反应层的宽度也逐渐变宽.创新点:研究铜-镍复合填充金属对Ti-6Al-4V(TC4)钛合金/304不锈钢焊接接头的微观组织、化合物组成以及力学性能的影响.