Cu、As和Sn对低合金钢连铸坯第Ⅲ脆性区的影响

为了研究残余元素Cu、As和Sn对钢高温延塑性的影响,采用Gleeble-1500热模拟试验机测试了含有一定量Cu、As和Sn低合金钢连铸坯的高温延塑性,得到了低合金钢第Ⅲ脆性温度区在920～730℃之间.结果表明:第Ⅲ脆性温度区脆化的主要原因是奥氏体单相区低温域钢中Cu、As和Sn等残余元素在奥氏体晶界的偏聚削弱晶界结合能,导致试样沿晶脆性断裂;奥氏体和铁素体两相区在原奥氏体晶界析出的网状铁素体导致试样沿晶开裂.钢中的Cu、As和Sn元素增加第Ⅲ脆性温度区的宽度和脆性凹槽的深度,同时提高第Ⅲ脆性温度区的上限临界温度.     

含铌钛钢X—52连铸坯的高温延塑性

测试了溶点－７００℃温度区间含铌钛钢Ｘ－５２连铸坯的高温延塑性。根据断口形貌、组织以及钢中析出物等的变化情况分析了该钢的脆化机理。结果表明：在熔点－７００℃温度区间，Ｘ－５２钢存在２个脆性区，熔点－１３８０℃的第Ⅰ脆性区，９２５－８２５℃的第Ⅲ脆性区。细小的ＮｂＣＮ沿奥氏体晶界的动态析出是造成第Ⅲ区脆化的主要原因。可通过向钢中添加少量的钛，以降低晶界处细小的ＮｂＣＮ的析出量，防止先共析铁素体在奥氏     

中碳亚包晶成分钢连铸坯角横裂的防止对策

宝钢生产的中碳亚包晶成分钢连铸坯角横裂属于沿晶界的开裂，主要发生在８５０℃以下温度，对３个钢种连铸坯试样的高温力学性能的测定表明，在ε＝４×１０＾－３／ｓ应变速率下，所测钢种在熔点～７００℃范围存在两个脆性温度区域，即熔点～１３５０℃的第Ｉ脆性温度区域和８５０～７２５℃的第Ⅲ脆性温度区域，在第Ⅲ脆性温度区域，γ单相域Ａ１Ｎ等氮化物在γ晶界的析出和在γ＋α两相区先共析α相呈网膜状，在γ晶界的析出是造     

合金弹簧钢连铸坯高温力学性能分析

为了时合金弹簧钢高温力学性能进行分析,采用Gleeble1500热模拟试验机测试了典型弹簧钢钢种SUP9、50CrVA、60Si2Mn的高温力学性能,绘制了3个钢种在600～1 350℃区间内的抗拉强度和热塑性曲线.应用扫描电镜对试样断口形貌进行观察,分析了3个钢种在不同温度区间的断裂机理,讨论了钢种成分及夹杂物对高温力学性能的影响.研究发现:SUP9、50CrVA、60Si2Mn存在第Ⅰ脆性区(Tm～1 315℃,Tm～1 281℃,Tm～1 316℃)和第Ⅲ脆性区(600～930℃,650～956℃,600～980℃).前者产生的原因是高温下枝晶间有害元素S、P和O富集形成液膜,后者是由于奥氏体晶界出现铁素体薄膜以及细小AlN的析出.     

高铝TRIP钢的高温力学性能

利用Gleeble3500试验机研究汽车用C-Mn-Al系TRIP钢的高温力学性能,测定了零塑性温度和零强度温度,应用差示扫描量热法测定其相变区间,采用扫描电镜和光学显微镜分析了不同拉伸温度对应的断口宏观形貌及断口附近组织组成.该钢种零塑性温度和零强度温度分别为1425℃和1430℃,第Ⅰ脆性区间为1400℃~熔点,第Ⅲ脆性区间为800~925℃.第Ⅲ脆性区脆化的原因是α铁素体从γ晶界析出,试样从975℃冷却至700℃过程中,随着α铁素体析出比例的增大,断面收缩率先减小后增大.基体α铁素体比例为8.1%时(850℃),断面收缩率降至28.9%;而拉伸温度在800℃以下时,基体α铁素体比例超过16.7%,断面收缩率回升至38.5%以上.该钢种在1275.6℃时开始析出少量粗大的AlN颗粒,但对钢的热塑性没有影响.     

中碳铝硅镇静钢连铸坯的高温延塑性

采用Ｇｌｅｅｂｌｅ－１５００热模拟实验机测试了宝钢生产的易出现角模裂纹缺陷的中碳铝硅镇静钢ＧＲ４１５１连铸坯的高温延塑性，并通过金相、扫描电镜等对拉断后试样的断口及组织形貌进行了分析检验。结果表明：ＧＲ４１５１钢在熔点￣７００℃的温度区间存在２个脆性区域，即熔点￣１３３０℃的第Ｉ脆性区和８６０￣７４０℃的第Ⅲ脆性区，γ单相域ＡＩＮ等氮化物在γ晶界析出在γ＋α两相区先共析铁素体叶网状并在γ晶界析出是     

中碳钢高温力学和冶金行为

采用Gleeble 1500热模拟机对CSP生产的SS400、Q235B和Q345B钢的热塑性进行了研究.结果发现,所研究的钢存在两个低塑性区,即凝固脆性温区(Tm～1 310℃)和低温脆性温区(850～725℃).试样断口金相和成分分析表明:产生凝固脆性温区的原因主要是高温下枝晶间有害元素S、P和O富集形成液膜;产生低温脆性温区的原因主要是奥氏体晶界出现铁素体薄膜以及细小AlN析出造成连铸坯的塑性降低.根据研究结果,提出了改善钢的热塑性防止铸坯裂纹的工艺建议.     

第三代汽车钢的热塑性及断裂机理

采用Gleeble-1500热模拟试验机,对第三代汽车钢(TG钢)在不同的变形温度下进行了热拉伸试验,研究其热塑性的变化.运用光学显微镜和扫描电镜分析了实验钢热变形的断口形貌及断裂机理.发现实验钢的强度随温度的升高而降低,热塑性曲线分为第Ⅰ脆性区、高温塑性区和第Ⅲ脆性区三个区域,其中第Ⅲ脆性区存在两个塑性极小值.在1300～800℃时实验钢的组织为奥氏体,断裂方式为连孔延性断裂,动态再结晶使韧窝分离前发生了较大的塑性变形,断口为大而深的韧窝;750℃时实验钢沿奥氏体晶界析出铁素体,断裂方式为界面断裂,断口既存在着铁素体内聚失效形成的小的孔洞,也存在由于裂纹沿奥氏体晶界扩展形成的石块状形貌;650℃由于出现了铁素体的准解理,实验钢的塑性下降,热塑性曲线再次出现极小值.     

第三代汽车钢的热塑性及断裂机理

采用Gleeble-1500热模拟试验机,对第三代汽车钢(TG钢)在不同的变形温度下进行了热拉伸试验,研究其热塑性的变化运用光学显微镜和扫描电镜分析了实验钢热变形的断口形貌及断裂机理.发现实验钢的强度随温度的升高而降低,热塑性曲线分为第Ⅰ脆性区、高温塑性区和第Ⅲ脆性区三个区域,其中第Ⅲ脆性区存在两个塑性极小值.在1300～800℃时实验钢的组织为奥氏体,断裂方式为连孔延性断裂,动态再结晶使韧窝分离前发生了较大的塑性变形,断口为大而深的韧窝;750℃时实验钢沿奥氏体晶界析出铁素体,断裂方式为界面断裂,断口既存在着铁素体内聚失效形成的小的孔洞,也存在由于裂纹沿奥氏体晶界扩展形成的石块状形貌;650℃由于出现了铁素体的准解理,实验钢的塑性下降,热塑性曲线再次出现极小值.     

49MnVS3非调质钢连铸方坯中心裂纹分析

采用金相、扫描电镜及能谱分析了连铸方坯中心位置的宏观和微观特征．发现偏析是导致中心裂纹产生的主要原因,裂纹发生在柱状晶末端和粗大等轴晶区,沿一次枝晶晶界展开;开裂方式为沿晶开裂,开裂时期处于液相．存在两种晶界偏析,一种为析出的MnS夹杂物,另一种为聚集的浓化钢液．中心位置析出物未达到非调质钢质量要求．     

X100管线钢焊接热影响区组织与韧性研究

采用热模拟试验技术,研究了X100管线钢焊接热影响区的组织与性能变化规律,结果表明:采用高Nb、微Ti设计的低碳X100管线钢的焊接粗晶区经焊接热循环后仍保持良好的韧性。焊接热影响区的脆化区出现在峰值温度为750℃的两相区。沿原奥氏体晶界形成的岛状组织是导致韧性降低的主要原因。     

高强度马氏体钢显微组织对腐蚀行为影响的研究进展

The high strength martensite steels are widely used in aerospace, ocean engineering, etc., due to their high strength, good ductility and acceptable corrosion resistance. This paper provides a review for the influence of microstructure on corrosion behavior of high strength martensite steels. Pitting is the most common corrosion type of high strength stainless steels, which always occurs at weak area of passive film such as inclusions, carbide/intermetallic interfaces. Meanwhile, the chromium carbide precipitations in the martensitic lath/prior austenite boundaries always result in intergranular corrosion. The precipitation, dislocation and grain/lath boundary are also used as crack nucleation and hydrogen traps, leading to hydrogen embrittlement and stress corrosion cracking for high strength martensite steels. Yet, the retained/reversed austenite has beneficial effects on the corrosion resistance and could reduce the sensitivity of stress corrosion cracking for high strength martensite steels. Finally, the corrosion mechanisms of additive manufacturing high strength steels and the ideas for designing new high strength martensite steel are explored.     

析出粒子对钛微合金化高强钢奥氏体晶粒长大的影响

通过析出粒子与奥氏体晶粒尺寸的定量关系,建立奥氏体晶粒长大模型,计算TiN和TiC析出粒子共同作用下钛微合金化钢奥氏体晶粒尺寸. 根据析出相质点理论计算结果表明:随着加热温度的升高,析出粒子体积分数逐渐减少,粒子半径逐渐增大,TiC粒子强烈阻止奥氏体晶粒长大,TiN粒子对奥氏体晶粒长大钉扎效果一般. 采用实验测试手段测量不同加热温度下保温30 min后实验钢的奥氏体晶粒尺寸,与理论计算结果吻合较好.     

Effect of microstructure on corrosion behavior of high strength martensite steel——A literature review

The high strength martensite steels are widely used in aerospace, ocean engineering, etc., due to their high strength, good ductility and acceptable corrosion resistance. This paper provides a review for the influence of microstructure on corrosion behavior of high strength martensite steels. Pitting is the most common corrosion type of high strength stainless steels, which always occurs at weak area of passive film such as inclusions, carbide/intermetallic interfaces. Meanwhile, the chromium carbide precipitations in the martensitic lath/prior austenite boundaries always result in intergranular corrosion. The precipitation, dislocation and grain/lath boundary are also used as crack nucleation and hydrogen traps, leading to hydrogen embrittlement and stress corrosion cracking for high strength martensite steels. Yet, the retained/reversed austenite has beneficial effects on the corrosion resistance and could reduce the sensitivity of stress corrosion cracking for high strength martensite steels. Finally, the corrosion mechanisms of additive manufacturing high strength steels and the ideas for designing new high strength martensite steel are explored.     

Metallographic etching and microstructure characterization of NiCrMoV rotor steels for nuclear power

The grain size of prior austenite has a distinct influence on the microstructure and final mechanical properties of steels. Thus, it is significant to clearly reveal the grain boundaries and therefore to precisely characterize the grain size of prior austenite. For NiCrMoV rotor steels quenched and tempered at high temperature, it is really difficult to display the grain boundaries of prior austenite clearly, which limits a further study on the correlation between the properties and the corresponding microstructure. In this paper, an effective etchant was put forward and further optimized. Experimental results indicated that this agent was effective to show the details of grain boundaries, which help analyze fatigue crack details along the propagation path. The optimized corrosion agent is successful to observe the microstructure characteristics and expected to help analyze the effect of microstructure for a further study on the mechanical properties of NiCrMoV rotor steels used in the field of nuclear power.     

微合金钢初始凝固中奥氏体开始长大的温度

通过共聚焦激光显微镜对P510L钢的初始凝固过程进行了原位动态观察以考察δ相生成、包晶反应以及γ相的形成过程,并探索奥氏体开始长大温度.研究结果表明:1)冷却速度为25℃/s时P510L钢的冷却模式为首先从液相中析出δ铁素体,然后在液相与δ铁素体相之间发生包晶反应(L+δ→γ),进入三相共存区,液相消失后剩余的δ相通过固态扩散转变为γ相;2)在初始凝固过程中,奥氏体先进行一部分吞并、长大,然后才实现过剩δ铁素体向奥氏体的同素异构转变,最后实现完全奥氏体化;3)通过原位动态观察,探索了一种较为准确的确定原始奥氏体开始长大温度的实验方法,提高了奥氏体晶粒预测模型的准确性.     

Effect of microstructure on the low temperature toughness of high strength pipeline steels

Microstructure observations and drop-weight tear test were performed to study the microstructures and mechanical properties of two kinds of industrial X70 and two kinds of industrial X80 grade pipeline steels. The effective grain size and the fraction of high angle grain boundaries in the pipeline steels were investigated by electron backscatter diffraction analysis. It is found that the low temperature toughness of the pipeline steels depends not only on the effective grain size, but also on other microstructural factors such as martensite-austenite (MA) constituents and precipitates. The morphology and size of MA constituents significantly affect the mechanical properties of the pipeline steels. Nubby MA constituents with large size have significant negative effects on the toughness, while smaller granular MA constituents have less harmful effects. Similarly, larger Ti-rich nitrides with sharp corners have a strongly negative effect on the toughness, while fine, spherical Nb-rich carbides have a less deleterious effect. The low temperature toughness of the steels is independent of the fraction of high angle grain boundaries.     

奥氏体化状态和钒对珠光体型钢轨钢韧性的影响

以重轨钢ＰＤ２和ＰＤ３为对象，重点研究了热轧态和重新热处理状态珠光体的韧性。研究结果表明，奥氏体状态（晶粒大小、成分均匀化及碳化物溶入或析出程度等）及珠光体的形态和片层间距是影响珠光体冲击韧性的主要组织因素。奥氏体晶粒的细化、珠光体片层的细化、奥氏体成分的均匀化及强碳化物形成元素在奥氏体状态的固溶化是珠光体钢韧化的基本途径。     

Effects of Si on the stability of retained austenite and temper embrittlement of ultrahigh strength steels

Effects of silicon (Si) content on the stability of retained austenite and temper embrittlement of ultrahigh strength steels were investigated using X-ray diffraction (XRD), transmission electron microscopy (TEM), and other experimental methods. The results show that Si can suppress temper embrittlement, improve temper resistance, and hinder the decomposition of retained austenite. Reversed austenite appears gradually with the increase of Si content during tempering. Si has a significant effect on enhancing carbon (C) partitioning and improving the stability of retained austenite. Si and C atoms are mutually exclusive in lath bainite, while they attract each other in austenite. ?-carbides are found in 1.8wt% Si steel tempered at 250℃, and they get coarsened obviously when tempered at 400℃, leading to temper embrittlement. Not ?-carbides but acicular or lath carbides lead to temper embrittlement in 0.4wt% Si steel, which can be inferred as cementites and composite compounds. Temper embrittlement is closely related to the decomposition of retained austenite and the formation of reversed austenite.     

High temperature strength and ductility of the (C+N) strengthening Fe-Cr-Mn(W,V) steels

Fe-Cr-Mn(W, V) austenite steels used as low radioactive structural materials in fusion reactor have been investigated. The resultsshow that the high temperature strength and the creep fracture life of Fe-Cr-Mn(W, V) steels can be effectively improved through (C+N) complex-strengthening, so can be the high temperature ductility. The strength and ductility of the steels are superior to that of SUS316 steels and JPCAS below 673K. The relationship between strength, ductility andthe formation temperature is related to the evolution of deformation microstructure. The fracture and microstructure observation above 673Kindicates that the main way to further improve ductility at high temperature is the control of carbide coarsening at the grain boundaries.