Welding of nickel free high nitrogen stainless steel: Microstructure and mechanical properties

High nitrogen stainless steel(HNS) is a nickel free austenitic stainless steel that is used as a structural component in defence applications for manufacturing battle tanks as a replacement of the existing armour grade steel owing to its low cost, excellent mechanical properties and better corrosion resistance.Conventional fusion welding causes problems like nitrogen desorption, solidification cracking in weld zone, liquation cracking in heat affected zone, nitrogen induced porosity and poor mechanical properties.The above problems can be overcome by proper selection and procedure of joining process. In the present work, an attempt has been made to correlate the microstructural changes with mechanical properties of fusion and solid state welds of high nitrogen steel. Shielded metal arc welding(SMAW), gas tungsten arc welding(GTAW), electron beam welding(EBW) and friction stir welding(FSW) processes were used in the present work. Optical microscopy, scanning electron microscopy and electron backscatter diffraction were used to characterize microstructural changes. Hardness, tensile and bend tests were performed to evaluate the mechanical properties of welds. The results of the present investigation established that fully austenitic dendritic structure was found in welds of SMAW. Reverted austenite pools in the martensite matrix in weld zone and unmixed zones near the fusion boundary were observed in GTA welds. Discontinuous ferrite network in austenite matrix was observed in electron beam welds.Fine recrystallized austenite grain structure was observed in the nugget zone of friction stir welds.Improved mechanical properties are obtained in friction stir welds when compared to fusion welds. This is attributed to the refined microstructure consisting of equiaxed and homogenous austenite grains.

Studies on Effects of Welding Parameters on the Mechanical Properties of Welded Low-Carbon Steel

In this work, the effect of heat input on the mechanical properties of low-carbon steel was studied using two welding processes: Oxy-Acetylene Welding (OAW) and Shielded Metal Arc Welding (SMAW). Two different edge preparations on a specific size, 10-mm thick low-carbon steel, with the following welding parameters: dual welding voltage of 100 V and 220 V, various welding currents at 100, 120, and 150 Amperes and different mild steel electrode gauges of 10 and 12 were investigated. The tensile strength, hardness and impact strength of the welded joint were carried out and it was discovered that the tensile strength and hardness reduce with the increase in heat input into the weld. However, the impact strength of the weldment increases with the increase in heat input. Besides it was also discovered that V-grooved edge preparation has better mechanical properties as compared with straight edge preparation under the same conditions. Microstructural examinations conducted revealed that the cooling rate in different media has significant effect on the microstructure of the weldment. Pearlite and ferrite were observed in the microstructure, but the proportion of ferrite to pearlite varied under different conditions.

Microstructure and pitting corrosion of shielded metal arc welded high nitrogen stainless steel

The present work is aimed at studying the microstructure and pitting corrosion behaviour of shielded metal arc welded high nitrogen steel made of Cromang-N electrode. Basis for selecting this electrode is to increase the solubility of nitrogen in weld metal due to high chromium and manganese content. Microscopic studies were carried out using optical microscopy(OM) and field emission scanning electron microscopy(FESEM). Energy back scattered diffraction(EBSD) method was used to determine the phase analysis, grain size and orientation image mapping. Potentio-dynamic polarization testing was carried out to study the pitting corrosion resistance in aerated 3.5% NaCl environment using a GillAC electrochemical system. The investigation results showed that the selected Cr-Mn-N type electrode resulted in a maximum reduction in delta-ferrite and improvement in pitting corrosion resistance of the weld zone was attributed to the coarse austenite grains owing to the reduction in active sites of the austenite/delta ferrite interface and the decrease in galvanic interaction between austenite and delta-ferrite.

压水堆一回路耐蚀层SMAW焊接工艺评定及技术实践分析

压水堆主设备一回路压力边界的主要材质为低合金钢,为了能有效降低腐蚀辐照活化产物的形成,一般要在低合金表面堆焊一层耐蚀层。根据ASME B&PVⅨ的要求,对影响焊条电弧焊SMAW的耐蚀层堆焊工艺评定的重要变素进行了分析,同时结合ASME B&PVCⅢ-NB的要求,对压水堆一回路中的SMAW耐蚀层焊接技术实践进行了探讨,为核电压水堆承压设备的耐蚀层SMAW焊接技术的提高提供参考。

大型往复式压缩机曲轴深度裂纹焊接修复

某企业一台大型往复式压缩机在检修时发现曲轴产生深度裂纹缺陷。对曲轴最危险截面进行强度校核,对曲轴材料焊接工艺进行抗裂性试验,对焊接方法进行比较与工艺分析,最终采用常温下手工氩弧焊的方法来恢复曲轴原有功能。

压力环境对焊条自动平焊过程及焊缝性能的影响

为了探究水下局部干法焊条电弧焊在40m以下水深环境下坡口内焊接的可行性,并探索合理的焊接参数,采用自主研发的焊条自动焊机构在压力舱中进行模拟20m和40m水深条件下的局部干法自动焊接试验。试验结果表明:在0.2MPa的模拟环境压力下的电弧稳定性优于常压,而在0.4MPa压力下电弧长度变化较为频繁,电弧稳定性有所降低。通过分析工艺试验结果,获得了在两种压力下焊缝成形良好的焊接参数。经力学性能测试验证,采用该焊接参数进行坡口内多层多道焊可以获得性能优良的焊接接头。

9Ni钢手工电弧焊焊接接头组织与性能研究

针对运输船用9Ni钢,研究手工电弧焊焊接工艺下9Ni钢焊接接头的组织与理化性能。组织分析表明,手工电弧焊下9Ni钢的焊缝组织由奥氏体和析出相组成,结晶形态为规则树枝状晶,且方向性较明显;焊接热影响区组织由板条马氏体组成,焊接粗晶区板条马氏体组织分布较均匀,偏析较分散,强韧性和机械性能不错。化学成分分析表明,9Ni钢板焊缝的化学成分与母材匹配性良好。焊接理化性能试验表明,手工电弧焊下焊接接头的低温韧性等性能满足标准要求,结合理论性能及断口分析,手工电弧焊焊接接头的低温韧性表现良好。

钨极氩弧焊焊接粉末冶金高铬铸铁/低碳钢的焊接性能及组织演变

以粉末冶金高铬铸铁和低碳钢为原材料,采用多道次手工钨极氩弧焊,研究了焊接电流对焊缝组织演变和力学性能的影响,提出了焊接接头组织演化模型,并探讨了其断裂机理。结果表明,焊接接头的抗拉强度在焊接电流为140 A时达到538.1MPa,分别是烧结高铬铸铁和低碳钢抗拉强度的95.3%和97.4%。由于二次回火和合金元素扩散/偏析的作用,焊接接头的显微硬度在水平方向上由高铬铸铁一侧向低碳钢一侧逐渐降低,而在垂直方向则呈M形分布。当焊接电流为140 A时,焊缝的熔合区主要由奥氏体和回火马氏体组成,在熔合区与低碳钢母材之间存在一个单一奥氏体柱状晶区;在熔合区与烧结高铬铸铁母材之间,存在一个柱状高铬铸铁区域,该区域的碳化物为粗糙树枝状,沿基体晶界分布。

负载持续率对手工弧焊机空闲损耗的控制研究

焊接是一种常见的金属连接方法,焊接过程中会产生大量的损耗,焊接结束后也会产生空闲损耗。本文旨在研究焊接负载持续率对焊机空闲损耗的有效控制,以优化焊接过程,降低焊接空闲损耗,提高焊接质量。文章依据标准GB 28736—2019的试验方法对焊接电流500 A以下的手工弧焊机进行试验验证,通过固定焊接周期对焊接时间进行调整,最终得出10分钟为一周期的手工弧焊机在保证正常焊接质量前提下在63%~64%负载持续率时一分钟的平均空闲损耗获得最低值。

船用EH690钢焊评及CTOD试验的工艺探讨

文章对100 mm的EH690钢进行了手工电弧焊的横对接、立对接位置焊接工艺评定,CTOD试验(焊缝中心、热影响区),为桩腿换新提供了技术支持。

搅拌摩擦焊与手工电弧焊接头电化学腐蚀性能研究

通过测定H65铜合金搅拌摩擦焊接头和手工电弧焊接头在3.5%NaCl溶液中的开路电位和极化曲线,研究其电化学腐蚀性能。结果表明,搅拌摩擦焊接头的抗腐蚀性能优于手工电弧焊接头。搅拌摩擦焊接头微观组织的细化、均匀化和致密化降低了晶界和晶粒在电化学上的不均匀性。手工电弧焊接头脱锌层和基体界面处产生的拉应力对抗腐蚀性能有较大影响。

核电用SA738Gr.B钢手工电弧焊焊接材料及工艺研究

采用国产和进口两种焊条，在不同焊接规范参数下焊接核电站安全壳用SA738Gr．B钢。对比和分析两种焊条焊缝金属抗拉强度和冲击功的变化规律，并探讨了焊缝金属的低温冲击值稳定性。结果表明，手工电弧焊焊接SA738Gr．B钢，该国国产焊条在焊接电流为120～140A，焊后热处理工艺为593~620C10h的实际工程应用条件下，能满足ASME相关规范和设计要求，完全可运用于实际焊接工程。

奥氏体不锈钢焊接接头在含硫介质中的腐蚀性

利用恒电位极化曲线法及金相显微分析方法,研究了奥氏体不锈钢手弧焊焊接接头在含Na2S溶液中的腐蚀行为。结果表明,采用A102焊条的焊缝,其耐蚀性优于A307焊条焊缝;20℃条件下,Na2S质量分数的增加加速腐蚀反应的阴、阳极过程;在Na2S质量分数一定的条件下,温度升高到80℃时,在阳极极化区有钝化现象。

热处理制度对TB2钛合金焊接接头性能的影响

研究了TB2高强钛合金冷轧板材分别经真空电子束焊和氩弧焊接,并在β单相区和α+β两相区温度固溶+时效处理后,其力学性能和显微组织的变化。结果表明:TB2钛合金具有良好的可焊性,任何焊接方法不同热处理下的接头强度系数均大于0.9,塑性均低于母材,其中710℃/30 mim AC+520℃/8 h处理的试样,综合力学性能较高,焊缝区内有弥散α析出的β晶粒,而且焊缝熔合线附近是整个焊缝的最薄弱部位;比较不同焊接方法,氩弧焊的接头强度较好,但塑性很差,热影响区较宽,晶粒长大明显。该试验结果为组焊成型TB2压力容器提供了参考。

水下湿法焊条电弧焊接过程稳定性评价

焊接电参数(电弧电压、焊接电流)包含着丰富的焊接过程信息.针对水下湿法焊条电弧焊工艺,在不同焊接工艺条件(不同水深、不同焊条)时在线采集焊接电弧电压瞬时值,然后对其进行统计处理.利用电弧电压标准差σU以及电弧电压瞬时值与电弧电压平均值差值H的频率对比和焊接过程稳定性指数W相结合的方式,对水下湿法焊条电弧焊接过程的稳定性进行直观分析和定量评价.结果表明,利用W可以很好地识别不同焊接过程的稳定性,为水下焊接工艺稳定控制提供了新的方法,具有重要的理论意义.

不同焊接方法和热处理对P92钢焊接接头组织及硬度的影响

采用手工电弧焊和钨极氩弧焊两种方法对P92钢板实施焊接,并对部分焊接接头进行焊后热处理。利用金相显微镜对不同焊接方法下热处理前后的焊接接头进行组织观察及对比,用硬度计对焊接接头的显微硬度进行测试。结果表明:热处理前,两种焊接方法得到的焊缝区及靠近焊缝的热影响区组织均为板条马氏体组织+残余奥氏体;经焊后热处理后,焊接接头组织均为回火托氏体。焊缝区向母材区过渡时,硬度值不断下降,经热处理后,焊接接头不同部位硬度相差较小。对比两种焊接方法,钨极氩弧焊的焊接线能量比手工电弧焊焊接线能量低0.56 kJ/m,热处理前后相同区域,钨极氩弧焊的组织更细小,硬度较高。

9Ni钢手工电弧焊和自动埋弧焊接头的组织及力学性能

采用手工电弧焊和自动埋弧焊分别对9Ni钢板进行焊接,通过拉伸、弯曲、冲击试验以及组织、断口观察等研究两种焊接接头的组织和力学性能。结果表明:两种焊接接头的焊缝组织均由奥氏体组成,热影响区均以马氏体为主;手工电弧焊接头焊缝的结晶形态呈树枝状,偏析程度较大,热影响区的马氏体粗大,自动埋弧焊接头焊缝的结晶形态为细小的胞状树枝晶,偏析程度较轻,热影响区的板条马氏体细小,板条束较多;两种焊接接头均具有良好的拉伸性能和弯曲性能,自动埋弧焊接头的低温冲击韧性优于手工电弧焊接头的;自动埋弧焊焊接接头冲击断口上的韧窝更大更深,且分布均匀。

手工电弧焊与CO_2气体保护焊焊缝成形特征研究

采用手工电弧焊与CO2气体保护焊对Q235钢板进行表面堆焊,研究了两种焊接方法的焊缝成形特征.结果表明,虽然手工电弧焊是气渣联合保护,有利于焊缝成形,但手工操作使得焊接速度难以保证匀速,导致焊缝表面粗糙,焊缝弯曲不平直;并且由于药皮焊条直径粗,导致手工电弧焊热影响区宽.而细丝CO2气保焊由于形成稳定的熔滴过渡,使得焊缝表面波纹细致、美观,焊缝平直,热影响区窄.CO2气保焊能精确控制焊接规范,可通过调节焊接规范来获得良好的焊缝成形,手工电弧焊不能精确控制焊接规范,不利于得到成形良好的焊缝.

摆动电弧水下湿法焊条电弧焊焊接控制及工艺

为进一步推动水下湿法焊条电弧焊的应用,设计并研制一套能实现水下电弧摆动功能的湿法焊条电弧自动焊接试验系统。利用该系统进行水下摆动电弧焊条电弧焊焊接试验。试验结果表明:该系统能实现稳定的水下焊接过程,焊缝熔宽均匀。随着摆动幅度和摆动频率的提高,焊缝熔宽均有增大的趋势,焊缝铺展性的确得到改善,但同时电弧稳定性均呈不同程度的下降趋势。此外在短弧焊接条件下,水下湿法焊接易产生短路过渡,焊接电流和焊接电压波形波动较大,但该现象在摆动频率为2Hz时有所改善。

逆变弧焊机电弧推力自适应控制系统

在焊接电流确定的条件下 ,引弧瞬间的焊机输出电压反映了焊接电缆长度、截面积以及地线连接情况等重要信息。本研究装置是基于MC6 8HC11单片机控制的逆变焊机电弧推力自适应控制系统 ,首先通过对引弧瞬间焊机输出电压的实时检测 ,实现了电弧推力拐点电压随焊接电流及焊接电缆长度、截面积等改变而自动调节 ;然后通过对焊接电弧电压的实时检测与模糊处理控制焊机的输出电流 。