INFLUENCE OF LOCAL BRITTLE ZONE ON THE FRACTURETOUGHNESS OF HIGH-STRENGTH LOW-ALLOYEDMULTIPASS WELD METALS

In this paper, toughness properties and microstructurc of low-alloyed multipass welds with yield strength above 700MPa have 6een studied using the weld thermal simulation and throughout thickness CTOD fracture mechanics tests. Impact testing of thermal simulated specimens showed that the primary weld metal and the fine gmmed weld metal had good toughness, while the coarse grained weld metal had the lowest toughness value as the local brittle zone (LBZ) in multipass weld metals. Cleavage fracture in CTOD testing of thick multipass weld metals was initiated from martensite-austenite (MA) phases in the LBZ. MA phases were distributed at the prior austenite grain boundaries and around ferrite grains. As the size of the local brittle zone along the fatigue crack front increases, CTOD frncture toughness of multipass weld metals decreases. The weakest link theory was used to evaluate effect of the local brittle zone on fracture toughness of thick multipass weld metals. The estimated curves agree well with the eaperimental data.

Microstructure and toughness of local brittle zone of HSLA steel multipass weld metals

By using thermo-simulation,Auger analysis and Charpy Ⅴ impact test and with the observation of the microstructures in which cleavage crack was initiated,the morphology and toughness of the local brittle zone of C-Mn and Cr-Ni-Mo multipass weld metals have been investigated.The results indicated that the local brittle zone in C-Mn weld metals with low and high Mn％ and Cr- Ni-Mo weld metals is different.With statistical analysis,it has been revealed that the more the local brittle zone and the lower their toughness,the lower the toughness of the entire weld metals.The alloy elements have a noticeable influ- ence on the toughness of the local brittle zone,thereby changing the toughness of weld metals.

Effect of Ti on the microstructure and mechanical properties of MAG multipass weld metal

Metal active gas （ MAG） welding has been carried out on microalloy controlled rolling steel （S355J2W） by two kinds of welding wires with different Ti content. The mechanical tests have been carried out on the welded joint. The optical microscope and scanning electron microscope （SEM） observations have been performed to investigate the effect of microalloy element Ti on the microstructure of weld metal and impact fracture, respectively. The microstrueture of the MAG multipass weld metal includes the columnar grain zone （CGZ） consisting of primary ferrite （ PF）, ferrite with second phase （FS） and acicularferrite （AF）, and the fine grain zone （FGZ） consisting of polygonal ferrite due to the heat effect of subsequent welding pass. It has been found that the small amount of Ti can significantly increase the impact energy of the weld metal at low temperature and weakly affect tensile strength of welded joint. By adding small amount of Ti, the inclusions have changed from Mn-Si-O inclusions to Ti-bearing inclusions, which causes the Mn-depleted zones（MDZs） much larger and is beneficial to the impact energy by promoting the AF formation, refining the PF and pinning the austenite grain boundary during the subsequent transformation process.

Welding Effect at the Heat Affected Zone by Joining a Gray Cast Iron with Stainless Steel E308-16

Different investigations of the union of dissimilar materials such as stainless steel and different castings have been carried out, but rapid cooling immediately after welding has not been considered, in this work it was investigated how rapid cooling affects the metallurgical microstructure and consequently the mechanical properties. The effect of welding parameters on the microstructure and mechanical properties of the joint between dissimilar metals, an E-308-16 austenitic stainless steel and Gray Cast Iron was also analyzed. Gray cast iron samples (GCI) were fabricated, welded and cooled. The main welding parameters studied in this work are the welding technique and the type of filler electrodes. Flux-coated electrode E-308-16 was applied for this different joint. An experimental study was carried out for the analysis of welded joints of similar and dissimilar steels. The microstructure of the welded joints was analyzed using an optical microscope, in the base metals, heat affected zone (HAZ) and filler metal. The mechanical properties of the welded joints were evaluated by Vickers microhardness and tensile strength tests. The hardness profile showed differences in hardness between the base metals, the heat affected zone and the filler metal. The metallurgical microstructures observed along the welded areas corresponded to the profile. The hardness differences determined the effect on the mechanical and metallurgical characteristics of the welded samples as a result of the cooling rate differences. This research work is important because it allows us to analyze the possibility of reworking pieces of dissimilar materials by welding or, failing that, to determine if this may or may not be possible.

Metallurgical characteristics of armour steel welded joints used for combat vehicle construction

Austenitic stainless steel(ASS) and High nickel steel(HNS) welding consumables are being used for welding Q&T steels, as they have higher solubility for hydrogen in austenitic phase, to avoid hydrogen induced cracking(HIC) but they are very expensive. In recent years, the developments of low hydrogen ferritic steel(LHF) consumables that contain no hygroscopic compounds are utilized for welding Q&T steels. Heat affected zone(HAZ) softening is another critical issue during welding of armour grade Q&T steels and it depends on the welding process employed and the weld thermal cycle. In this investigation an attempt has been made to study the influence of welding consumables and welding processes on metallurgical characteristics of armour grade Q&T steel joints by various metallurgical characterization procedures. Shielded metal arc welding(SMAW) and flux cored arc welding(FCAW) processes were used for making welds using ASS, LHF and HNS welding consumables. The joints fabricated by using LHF consumables offered lower degree of HAZ softening and there is no evidence of HIC in the joints fabricated using LHF consumables.

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.

Characterization of Dissimilar Welding between 304 Stainless Steel and Gray Iron Using Nickel Coated Electrode

This paper presents the study carried out to study the microstructure and mechanical properties of AISI 304 stainless steel and gray iron, in order to recognize the effect of welding parameters on the joint. The shielded metal arc welding technique was applied with a 3.2 mm diameter nickel coated electrode under preheating and post heat conditions at 350°C. Vickers hardness test and metallographic analysis were carried out at the heat affected zone and at the interface to determine the effect on mechanical and metallurgical characteristics. Vickers hardness differences among joint areas were directly related to microstructural changes. There are no significant differences in AISI 304 hardness, but the hardness increased at the heat affected zone and decreased at the filler metal. Grey iron hardness at the heat affected zone was even lower and more slightly superior than grey iron hardness.

C-Mn-Ti-B超高强度钢焊接熔合区的形成过程及其组织转变

研究了C -Mn -Ti-B超高强度钢焊接熔合区及其组织转变 ,发现焊接接头的最高硬度位于熔合区和富奥氏体带 ,而不是通常所认为的淬火区 ;富奥氏体带的化学成分及浓度接近于焊缝金属中的成分与浓度。考虑焊接接头所经受的热循环、元素扩散以及室温下焊接接头的组织、成分变化 ,提出了一种新的富奥氏体带形成机制并建立了熔合区的过程模型。该模型认为 :焊接热作用下的焊接接头可划分为三个特征区域 :熔化区、固液共存区和固相区 ;在冷却过程中 ,熔化区转变为富奥氏体带和焊缝混合区 (α+γ组织 ) ;固液共存区转变为熔合区 ;固相区转变为通常意义下的纯热影响区和未发生变化的基体。根据此模型 ,成功地解释了熔合区类马氏体组织和含碳硼化物 (Cr、Fe) 2 3 (C、B)

低合金高强钢多层焊缝薄弱环节的组织及韧性

以C-Mn,Cr-Ni-Mo手工多层焊缝为研究对象,采用示波冲击,俄歇分析,启裂源组织观察及热模拟实验,对薄弱环节组织的形态,韧性及对焊缝韧性的影响进行了研究.结果发现.低Mn%,高Mn%的C-Mn焊缝及Cr-Ni-Mo焊缝中的薄弱环节足不同的.统计分析表明,薄弱环节组织数量越多,韧性越低,焊缝的韧性就越低,合金元素对薄弱环节的韧性有影响,从而影响整个焊缝的韧性.

2205双相不锈钢的焊接工艺研究

在2205双相不锈钢焊接过程中,通过对焊缝金属和焊接热影响区内金属相变的分析研究,总结出了合理的焊接工艺。

高强钢多层焊缝薄弱环节组织及韧性的研究

本文采用示波冲击,俄歇分析,启裂源组织观察,热模拟等实验,对Cr—Ni—Mo 70kg/mm^2手工多层焊缝中各种组织的形态及韧性进行了研究。其中韧性较低的是经850℃—1050℃再热后的重结晶及不完全重结晶组织,韧性最薄弱环节主要为具有黑色带状的重结晶组织,其构成为铁素体及带状分布的M—A组元或碳化物。薄弱环节数量越多韧性越低,整个焊缝的韧性就越低;合金元素通过影响薄弱环节的韧性而改变整个焊缝的韧性。

用SZ法测试焊缝金属延性断裂韧度的研究

采用SZ法对焊缝金属的延性断裂韧度进行了测定并作了线性回归分析 ,分析了SZ法的特点 ,并对其关键技术作了探讨。最后建议对于高延性材料采用SZ法 。

铝/镀锌钢板CMT熔钎焊界面区组织与接头性能

采用冷金属过渡方法(CMT)对铝和镀锌钢板异种材料进行了熔钎焊连接。使用扫描电镜(SEM)、能谱分析(EDAX)和拉伸试验对焊接接头界面区显微组织及接头性能进行研究。试验结果表明,铝和镀锌钢能得到成形良好的搭接接头。在CMT熔钎焊的方法下,形成了中间厚两边薄的界面区,并且在熔化区一侧边缘形成了富锌区,界面区组织成分也由致密的FeAl3金属间化合物层变为α固溶体和FeAl3化合物混合层,而富锌区是由富铝的α固溶体和残留的铝组成。在进行拉伸试验时,断裂发生在铝母材的热影响区,接头强度为72.09 MPa。

大尺寸金属焊接接头低温CTOD试验研究

完成了用于寒冷海区半潜式采油平台的高韧性金属材料大尺寸焊接试件焊缝金属区及焊接热影响区的 CTOD(裂纹尖端张开嘴位移 )试验 ,获得了焊缝金属区和热影响区的低温CTOD值 ,讨论了试验方法及试验现象 .

放电电压对镁-铝磁脉冲焊接中金属射流及结合界面的影响

近年来,磁脉冲焊接技术凭借其在异种金属焊接中的独特优势展现出广阔的应用前景。放电电压是磁脉冲焊接过程中重要的电气参数,而金属射流可清理工件表面的污秽和氧化层,促进金属的冶金结合。为探究放电电压对金属射流及结合界面的影响,该文对放电电压与金属射流特征、结合界面形貌之间的内在联系进行理论分析,并建立镁-铝磁脉冲焊接综合实验观测平台,捕捉到完整的金属射流轨迹。结果显示,当放电电压从13kV提高到16kV时,碰撞速度从403.12m/s提高到了498.49m/s,对碰撞角度无明显影响;金属射流持续时间从31.02μs增加到47.94μs,且射流强度也逐渐增强。金相显微镜测试结果表明,放电电压为14kV、15kV、16kV时,镁-铝结合界面呈现波纹界面,且波幅不断增大,结合区域宽度分别为1.27mm、1.35mm、1.77mm。放电电压通过碰撞速度、碰撞点速度、碰撞压力及碰撞后剩余能量改变金属射流特征及结合界面形貌从而影响焊接效果。该文可为深入研究磁脉冲焊接机理、提高焊接效果提供有力参考。

金属磁记忆法检测焊接裂纹的时间空间有效性

预制了焊接裂纹试板,在试板的不同空间区域,以及焊接之后的不同时刻进行了金属磁记忆检测。采用快速傅里叶变换对检测信号进行了特征分析,研究了焊接裂纹周围不同区域在不同时刻的金属磁记忆信号以及其傅里叶变换相位突变特征。结果表明,在焊接裂纹存在的70mm范围内是金属磁记忆检测的空间有效区域。在焊接完成后,接头温度低于100℃以后的任何时间进行金属磁记忆检测,取得的结果都是有效的。

T91/10CrMo910焊接接头韧性分析

采用硬度试验、示波冲击试验、SEM断口分析、金相组织分析等,对电厂服役一年的T91/10CrMo910焊接接头的冲击韧性进行了分析。结果表明:焊缝区为准解理型脆性破断;10CrMo910热影响区和T91热影响区为微孔聚合韧窝型韧性破断。焊缝区组织为粗大的板条马氏体,并且焊后回火不充分,韧性差;10CrMo910热影响区和T91热影响区的组织分别为索氏体和细的回火马氏体,韧性较好。示波冲击曲线与断口形貌和硬度以及组织有良好的对应关系,是韧性分析的有效方法之一。

低合金高强钢焊接金属中残余氢的研究

以连续加热测氢方式研究了低合金高强钢焊缝金属及焊接热影响区金属中的氢陷阱以及残余氢的逸出行为。结果表明:焊缝金属中的残余氢存在于空洞、夹杂物边界等强陷阱和位错、晶粒边界等弱陷阱中;而焊接热影响区金属中的残余氢则主要存在于位错、晶粒边界等弱陷阱中。弱陷阱中氢的释放温度较低,它对焊接接头性能的影响值得重视。

焊缝金属强度匹配与扩散氢的关系

综述了焊缝金属强度匹配与扩散氢的关系。结果表明,常用焊接方法焊缝中氢的来源主要是焊接材料中的水分、坡口杂质及电弧周围的水气等。在焊缝中氢的影响因素中,GMAW方法扩散氢最低,电弧中除氢冶金反应取决于焊接方法,辅助除氢工艺作用不可小觑。高强钢采用低强匹配焊缝时,HAZ形成富氢带,是接头的薄弱环节;采用高强匹配焊缝时,HAZ富氢带不显著,而焊缝中的氢含量高,成为接头的薄弱环节。三种焊缝强度匹配与扩散氢关系的工程应用均获得了满意的工程质量;在马氏体耐热钢及其异种钢焊接中,高强匹配焊缝阻止HAZ形成富氢带的创新理论,尚需深入研究。

激光焊接对块体非晶合金Zr_(45)Cu_(48)Al_7晶化行为的影响

采用激光焊接技术连接块体非晶合金Zr45Cu48Al7(摩尔分数,%)。结果表明:在焊接热循环作用下,熔化区和热影响区的晶粒形貌和组织具有很大的差异;焊接速率为2 m/min时,熔化区主要生成5τ(Zr38Cu36Al26)、ZrCu和一未知相,热影响区主要生成ZrCu相;焊接速率为4 m/min时,熔化区保持了非晶特性,热影响区部分晶化,其主要生成相为ZrCu相;热影响区的晶化行为与非晶合金热处理过程的晶化行为有一定的区别,其主要原因是激光焊接时的高速加热及冷却过程对各晶化相生长速率影响程度不同。