低碳低合金钢焊缝金属的显微组织及其影响因素

低碳低合金钢焊缝金属的显微组织基本上包括先共析铁素体、针状铁素体、侧板条铁体、少量的粒状贝氏体和马氏体。分析了这些组织的形成条件及特点,焊缝金属化学成分和冷却速度是影响焊缝金属组织的主要因素,阐述了各种组织的形核位置。低碳低合金钢焊缝金属最理想的组织是获得大于６５％的针状铁素体,其平均板条尺寸约为１μｍ。     

Mn-Si对ZG1Cr11Ni2WMoV钢力学性能的影响

采用金相显微镜、扫描电镜和拉伸试验机研究了少量硅锰含量对铸造ZG1Cr11Ni2WMoV马氏体耐热钢显微组织和力学性能的影响。结果表明:显微组织主要由板条状回火马氏体和沿原奥氏体晶界分布的δ-铁素体组成,力学性能方面,少量硅-锰使耐热钢强度具有升高趋势。     

高碳贝氏体钢的低温转变组织与性能

摘要：采用光学与扫描电子显微镜、X射线衍射等手段研究了不同等温温度（300、250、200℃）对于高碳（质量分数0.79%）贝氏体钢低温转变样品的相含量、组织尺寸和力学性能的变化规律。结果表明,随贝氏体等温温度的降低,贝氏体最终转变量更高,贝氏体铁素体板条和薄膜状残余奥氏体宽度、块状残余奥氏体尺寸减小,抗拉强度升高,塑韧性降低。300℃的贝氏体抗拉强度为1525MPa,贝氏体铁素体宽度是116nm,而200℃的贝氏体铁素体板条尺寸达到62nm,抗拉强度达到1 928MPa。研究发现,在未充分转变的贝氏体样品中,尺寸大于4.7μm的块状残余奥氏体在冷却过程中易发生马氏体相变,而小于该尺寸的残余奥氏体比较稳定,可以保留到最终组织中。     

不同强度级别低合金钢焊缝金属的组织特征及其对韧性的影响

焊接区的微观组织是决定其力学性能的关键因素。为了改善低合金钢焊缝的冲击韧性,对500~1 000MPa级焊条的焊缝金属的化学组成、金相组织和力学性能进行了对比研究。采用金相显微镜和透射电子显微镜对不同强度级别的低合金钢焊缝组织进行了观察和电子衍射分析,并进行了焊缝金属拉伸强度和冲击韧性测试。结果表明,随着焊条强度级别的增加,焊缝组织由先共析铁素体、针状铁素体加珠光体变成粒状贝氏体,最后变成贝氏体加马氏体组织;当焊缝组织为粒状贝氏体时其韧性最低。     

热加工对含氮马氏体不锈钢组织转变和性能的影响

采用Thermal-calc计算了含氮马氏体不锈钢20Cr13的合金相图,据此进行了关键热加工工艺参数设计。采用金相、扫描电镜、X射线衍射、高温热模拟试验、拉伸试验和硬度测试等方法,研究了高温下均热温度对高温组织转变的影响以及高温铁素体对高温塑性的影响,同时研究了退火和淬火工艺对组织和性能的影响。结果表明:铸锭中的少量δ铁素体在单相奥氏体区高温长时间均热后并未消除;δ铁素体的存在降低了马氏体不锈钢的高温塑性;在临界温度长时间退火后,组织为铁素体基体上弥散分布球状碳化物的索氏体及沿晶界呈断续分布的点状碳化物,随退火温度的提高,索氏体晶粒尺寸增大,碳化物选择性地在晶界粗化长大,并呈断续状点状分布;950~1100℃奥氏体化淬火后的组织为板条马氏体+碳化物+少量残余奥氏体。淬火温度较低时,碳化物和残余奥氏体含量较高,淬火后马氏体硬度较低,提高淬火温度,碳化物充分溶解,奥氏体中的碳含量增加,淬火后板条马氏体硬度升高。     

激光焊接速度对焊缝组织和硬度分布的影响

利用激光焊接工艺焊接核级不锈钢,通过改变激光焊接速度得到不同的焊接接头.采用金相显微镜、扫描电子显微镜等手段研究了熔深比、δ/γ比、组织形貌以及焊缝中各相的成分.通过显微硬度测试了焊缝接头上硬度分布.随着焊接速度的增加,焊缝熔深比线性增加,焊缝中δ-铁素体含量增加,岛状组织增多,板条状组织增多,蠕虫状组织减少,焊缝区的平均硬度值增加.      

2 GPa中碳中锰纳米贝氏体钢的相变和塑性机理

 高碳(质量分数为0.78%~0.98%)高硅(质量分数约为1.5%)钢采用低温贝氏体转变(通常为150~250 ℃),可获得不小于2.0 GPa超高强度,但塑性较低(通常不大于8.0%);同时需要非常长的贝氏体相变时间(通常不小于4 d)。采用降低碳含量(Fe-0.30C-1.5Si-1.5Ni)的成分设计,可以显著加速贝氏体相变(300 ℃等温0.5 d),获得优良强度(抗拉强度(1 138±6) MPa)和塑性(伸长率为18.5%±1.5%)匹配的性能;但很难达到超高强度(1 500 MPa)级别。参考高/中碳贝氏体钢的合金设计、显微组织和力学性能特点,采用“中碳、以铝代硅、以锰代镍”的合金成分(Fe-0.30C-1.2Al-5.0Mn)体系,在M_s(马氏体开始转变温度)温度(300 ℃)附近进行贝氏体相变,可以获得强度为2.0 GPa级((2 029±9) MPa),伸长率超过10.0%(11.5%±1.0%)的高塑性纳米贝氏体钢,同时贝氏体相变时间适中(等温2 d),合金制造成本低廉(镍质量分数约为0.5%)。Fe-0.30C-1.2Al-5.0Mn钢具有超高强度主要是由于硬相组织贝氏体铁素体和马氏体总体积分数为85.1%,其中贝氏体铁素体板条宽度为(85±30) nm。具有较高塑性主要是由于软相组织残留奥氏体的体积分数为14.9%,碳质量分数为1.12%,位于贝氏体铁素体板条之间的薄膜状残留奥氏体尺寸为(30±15) nm;同时碳、锰元素能够增加残留奥氏体稳定性,特别是相对于低锰含量,5%中锰元素对残留奥氏体有更显著的稳定性作用,使其在低应力作用下不容易发生相变,但在高应力过程中持续发生TRIP效应以提高塑性。     

中碳Cr-Mo-V钢连续冷却时的组织转变规律

采用Formastor-FⅡ全自动相变仪实现不同冷却速度,利用金相显微镜、扫描电子显微镜和透射电子显微镜,研究了45CrMoV钢在不同冷却速度下的组织转变规律以及回火温度对组织的影响。结果表明,随着冷却速度的变慢,45CrMoV钢的组织由马氏体变为马氏体、先共析铁素体、下贝氏体和粒状贝氏体的混合物。冷却速度进一步变慢,先共析铁素体数量增多,下贝氏体和粒状贝氏体总量减少,材料硬度不断下降;45CrMoV钢中的粒状贝氏体为岛状、颗粒状,也有不规则形状,下贝氏体铁素体板条比低碳钢和超低碳钢中的板条更宽,分布更分散,板条形态不规则;随着回火温度的升高,45CrMoV钢中的渗碳体由细针状变为细条状,最后长大为椭球状,材料强度下降,韧性上升。     

细晶强化和位错强化对中锰马氏体钢的强化作用

 研究了碳和锰含量对淬火中锰马氏体钢的位错密度、残余奥氏体含量、晶粒尺寸等组织结构以及室温力学性能的影响。借助于SEM、EBSD、TEM和XRD表征了材料的微观组织,探讨了马氏体钢的强化机制。结果表明:随着碳含量增加,淬火中锰钢的位错密度和残余奥氏体体积分数逐渐增加,板条束和板条块尺寸逐渐细化,大角晶界百分数逐渐增加,强度逐渐升高;增加锰含量能够提高马氏体钢的位错密度和抗拉强度。分析认为,位错强化和细晶强化是淬火中锰马氏体钢的主要强化机制。马氏体板条尺寸是马氏体抗拉强度的结构控制单元,而原奥氏体晶粒尺寸则是马氏体屈服强度的结构控制单元。     

C-Si-Mn-B系贝氏体钢的强度及强化机制

测定并分析了中碳和中低碳C-Si-Mn-B系贝氏体钢的抗拉强度及强化机制，结果表明，该钢具有较高的强度和良好的塑性，减小贝氏体铁素体板条宽度和提高板条内的位错密度对贝氏体的强化有较大贡献，在贝氏体/马氏体复相组织的强化机制中，应考虑下贝氏体板条对原奥氏体晶粒的分割细化效应以及马氏体对贝氏体板条变形的约束作用。由强化机制计算的强度值与实测值有较好的一致性。     

Microstructural, compositional, and microhardness variations across a gas-metal arc weldment made with an ultralow-carbon consumable

An experimental gas-metal arc (GMA) weldment of HSLA-100 steel fabricated with an ultralowcarbon (ULC) consumable of interest for United States Navy applications, designated “ARC100,” was studied to determine the relationships among the microstructure, the solute redistributions at various positions across the weldment, and the local properties (microhardness). These relationships were investigated by a variety of techniques, including microhardness mapping, optical microscopy, transmission electron microscopy (TEM), scanning electron microscopy (SEM), energy-dispersive spectroscopy (EDS) (including compositional X-ray mapping), and parallel electron energy-loss spectroscopy (PEELS). The microconstituents observed in this weld include lath ferrite, degenerate ferrite, lath martensite, retained austenite, and oxide inclusions; no carbides or other solid-state precipitates are present within the weld metal. Microhardness mapping indicates an undermatched weld metal (lower hardness as compared to the base plate) in which the hardest regions are in the first and last top beads, the root passes, and between highly ferritic soft bands associated with the outer portion of each weld bead’s heat-affected zone (HAZ) (within the fusion zone). The majority of the gradient in the substitutional alloying elements (Ni, Cu, Mn, and Cr) occurs within a region of less than about 0.5 mm of the fusion boundary, but the composition still changes even well into the fusion zone. Appreciable segregation of Ni and Cu to solidification cell boundaries occurs, and there is appreciable enrichment of C, Ni, Cu, and Mn in thin films of interlath retained austenite. This ULC weld metal is softer than the base plate due to the preponderance of lath ferrite rather than lath martensite, even at the high cooling rates experienced in this low-heat-input weld. Alternatively, the strength of the weld metal is due to the presence of at least some untempered lath martensite and the fact that the majority of the ferrite is lath ferrite and not polygonal ferrite. The interlath retained austenite might enhance toughness, but might also serve as a source of hydrogen in solution, which could potentially contribute to hydrogen-assisted cracking.     

Microstructural evolution in ultra-low-carbon steel weldments—Part I: Controlled thermal cycling and continuous cooling transformation diagram of the weld metal

The transformation behavior and microstructural evolution of the as-deposited weld metal from an ultra-low-carbon (ULC) weldment were characterized by dilatometry, optical microscopy, transmission electron microscopy, and microhardness measurements. These results were used to construct a continuous cooling transformation (CCT) diagram for this weld metal. The major microconstituents observed in this ULC weldment were (in order of decreasing cooling rate) coarse autotempered martensite, fine lath martensite, lath ferrite, and degenerate lath ferrite. No polygonal ferrite was observed. These results were also used to develop criteria to differentiate between the two predominant microstructures in these ULC steels, lath martensite, and lath ferrite, which can look quite similar but have very different properties.     

锰对中锰耐磨钢组织形态及相变的影响

通过DIL805A热分析仪、扫描电子显微镜、电子背散射衍射、透射电子显微镜、力学分析等方法研究Mn对中锰耐磨钢组织形态、相变及力学性能的影响.随着Mn的质量分数以2%的增量从3%提高到9%,室温奥氏体含量逐渐增多,抗拉强度及硬度逐渐降低,抗拉强度和室温奥氏体体积分数都在5%到7%时变化明显,马氏体与奥氏体的位向关系发生改变,马氏体形态类型逐渐由亚结构以位错为主的板条状α马氏体变化为亚结构以位错、相变内孪晶和层错为主的束状细片α马氏体和细片状ε马氏体.      

Effects of Dual-Phase Region Quenching Treatment on Microstructure and Mechanical Properties of 24CrNiMo Low-Alloy Steel Prepared by Selective Laser Melting

Herein, 24CrNiMo low-alloy steel is successfully prepared using selective laser melting (SLM) technology. Effects of dual-phase region quenching treatment on microstructure and mechanical properties of SLM 24CrNiMo low-alloy steel are analyzed. The results show that after three kinds of dual-phase region quenching treatment, different martensite–ferrite dual-phase microstructure of the as-quenched alloy steel is obtained. In the range of austenitizing temperature from 760 to 820 °C, the content and size of the ferrite decrease; on the contrary, the content and size of the martensite increase. Furthermore, with the austenitizing temperature increasing, the morphology of the ferrite gradually changes from acicular ferrite + polygonal ferrite to acicular ferrite, while the lath characteristics of the martensite become more and more obvious. For electron backscatter diffraction results, with increasing the quenching temperature, the crystallographic morphology gradually changes from columnar grains to equiaxed grains; meanwhile, the extreme value of texture strength and the average size of grains are both decreased. When the austenitizing temperature is 820 °C, the microhardness and tensile strength of the as-quenched alloy steel are much higher than that of the as-deposited alloy steel.     

Microstructure Evolution and Precipitation Behavior of 0Cr16Ni5Mo Martensitic Stainless Steel during Tempering Process

The microstructure,morphology of precipitates and retained austenite and the volume fraction of retained austenite in 0Cr16Ni5 Mo stainless steel during the tempering process were analyzed using optical microscope(OM),transmission electron microscope(TEM),X-ray diffraction(XRD)and scanning transmission electron microscope(STEM).The results show that the microstructure of the tempered steel is mainly composed of tempered martensite,retained austenite,and delta ferrite.In the case of samples tempered from 500 to 700 ℃,the precipitates are mainly M_(23)C_6,which precipitate along the lath martensite boundaries.The precipitate content increases with the tempering temperature.During the tempering process,the content of retained austenite initially increases and then decreases,the maximum content of retained austenite being 29 vol.% upon tempering at 600 ℃.TEM analysis of the tested steel reveals two morphology types of retained austenite.One is thin film-like retained austenite that exists along the martensite lath boundary.The other is blocky austenite located on packet at the boundary and the original austenite grain boundary.To further understand the stability of reversed austenite,the Ni content in reversed austenite was measured using STEM.Results show a significant difference in nickel concentrations between reversed austenite and martensite.     

回火温度对淬火后30MnB5热成形钢组织与性能影响

将30MnB5热成形钢进行淬火和回火处理,利用扫描电镜、透射电镜、能谱仪和拉伸性能检测等方法研究了不同回火温度后的显微组织和力学性能变化.经200℃保温2 min回火后热成形钢的综合力学性能最佳,抗拉强度为1774 MPa,总伸长率为8%,强塑积达14 GPa·%以上,该性能满足热成形后作为汽车结构件的使用要求;并且随着回火温度的升高,力学性能呈非单调性变化.200℃低温回火后,主要为板条马氏体和ε碳化物,位错密度略有降低,析出的ε碳化物粒子呈针状分布在马氏体板条内,长度方向大小为100 nm左右,并与位错发生钉扎作用.随着回火温度的升高,板条马氏体发生回复和再结晶,板条边界逐渐模糊,并向等轴状铁素体转变,位错密度显著降低,ε碳化物逐渐向低能态的近球形渗碳体转变并粗化至200 nm左右,对位错的钉扎作用也随之减弱.      

Analysis Microstructure of Weld Metal for HQ130+QJ63 High Strength Steel

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Fe-Based Filler Material Forming Austenite-Covered Packet Lath Martensite for Gas Tungsten Arc Welding of 9% Ni Steel

Fe-based filler material with a composition of Fe–20Ni–5Co–2.5Mn–0.2C is developed for welding 9% Ni steel. To ensure high weldability through compositional similarity, the composition of the Fe-based filler material is designed based on that of 9% Ni steel. The filler material has elements such as Ni, Mn, Co, and C to enhance its compatibility with the 9% Ni steel. The Fe-based filler material is designed to control the martensite formation temperature, resulting in the appearance of the martensite–austenite dual phase during rapid cooling. The weld joint shows a distinct microstructure characterized by the presence of austenite-covered packet lath martensite. The mechanical properties of the weld joint are investigated via Vickers harness and tensile tests at 25 and −163 °C. In comparison to 9% Ni steel, the weld joint prepared using the Fe-based filler material exhibits yield and tensile strengths that are ≈5.5% higher. Additionally, the tensile fracture of the specimen occurs exclusively within the base metal, without any involvement of the weld metal or heat-affected zone. Further, the fracture surface is observed. In the findings of this study, the applicability of the Fe-based filler material for welding 9% Ni steel is demonstrated.     

低成本工程机械用Q690E级高强钢的热处理工艺与工业化

  以低成本、高附加值Q690E级调质板开发为目标,研究了亚温热处理与调质热处理工艺参数对试验钢显微组织与力学性能的影响。结果表明：在进行810℃亚温淬火处理的前躯体中存在大块状的铁素体时,易导致试验钢的低温冲击韧性恶化;以板条马氏体为前躯体经相同亚温淬火后,显微结构为更加细小的马氏体和以条状形态呈平行趋势分布在马氏体之间的铁素体两相混合组织,试验钢的-40℃冲击功值高达247J,但强度较低;常规调质热处理后的试验钢具有良好的综合力学性能,采用修正后的工艺参数,工业试制6~60mm规格产品的强韧性能均明显超过相关标准要求。