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1.
利用热膨胀试验研究了9Cr钢随冷却速度变化的相变行为,设定奥氏体化温度分别为860和1000℃,利用 OM、SEM、TEM、XRD和室温拉伸对比研究不同热处理温度下9Cr钢的显微组织及力学性能.研究表明:随着冷却速度增加,9 Cr 钢发生铁素体/珠光体相变、贝氏体相变和马氏体相变,其中马氏体相变临界冷速为1.6℃/s;860℃热处理后9Cr钢的显微组织为板条贝氏体/马氏体和少量等轴铁素体,并有4%的残余奥氏体;奥氏体化温度升至1000℃后,奥氏体晶粒尺寸增加,9Cr 钢中铁素体几乎消失,板条特征更加明显,力学性能与860℃热处理后基本相同,均达到 HL级抽油杆钢的要求,说明9Cr钢具有较宽的工艺窗口. 相似文献
2.
针对油轮货油舱底部的高氯离子强酸性腐蚀环境,参照了IMO《货油舱用耐蚀钢实验程序》的要求,深入研究了腐蚀溶液的pH值对其腐蚀特性的影响,对比分析了普通E36级船板钢以及等强度级别的耐蚀船板钢腐蚀行为的差异.研究结果表明,pH值对钢的腐蚀速率有显著影响.pH<3.0时,耐蚀钢的耐腐蚀性能,尤其是耐点蚀性能明显优于传统钢;pH≥3.0时,耐蚀钢和传统钢的腐蚀速率未表现出明显差异.强酸性氯离子环境下,实验钢的纯净度、微量耐蚀合金设计、显微组织共同决定了其耐腐蚀性能.钢中的非金属夹杂物是诱发局部腐蚀的主要原因;Cu、Ni、Sn元素的复合添加能显著提高耐蚀钢的腐蚀电位,同时耐蚀合金元素在锈层内部富集,提高了耐蚀钢表面锈层的致密性与稳定性;单一均匀的贝氏体显微组织有利于提高实验钢在酸性氯离子环境下的耐蚀性能,这主要是由于贝氏体组织中富碳相较少且分布均匀. 相似文献
3.
The two types of microstructure of low carbon and high chromium steel (5Cr) were obtained through the test smelting, rolling and quenching after rolling.Corrosion performance of 5 mass%Cr steel and Q235 steel were researched by means of cyclic wetting and drying corrosion test in 2 mass% NaCl solution.Corrosion behavior and corrosion rust layers were analyzed by OM, SEM, EDS, XRD, cyclic wetting and drying corrosion tester and electrochemical testing. The results show that after the specimens were immersed and etched in 2 mass% NaCl solution for 72h, the different microstructures of 5Cr steel have great influence on the resistance to chloride ion corrosion. B+F+M microstructure of 5Cr steel shows lower corrosion rate than Q235 steel, 5Cr steel with martensite microstructure also shows lower corrosion rate than Q235 steel. Corrosion susceptibility of 5Cr steel with martensite structure is weaker than complex organization.The stratification of chromium oxide, oxyhydroxide, and iron oxide exists in the chromium- containing steel rust layer, in which the Cr enrichment maximum value is 17 mass%, and the lowest is 1 mass%.Lath martensite formed by quenching process makes the corrosion potential rise, ??- FeOOH and ??- FeOOH form. Bainite+ferrite phase and adverse phenomenon of Cr steel may cause the poor corrosion resistance. 相似文献
4.
Dry sliding wear tests of a Cr-Mo-V cast hot-forging die steel was carried out within a load range of 50-300 N at 400 ℃ by a pin-on-disc high-temperature wear machine. The effect of heat treatment process on wear resistance was systematically studied in order to select heat treatment processes of the steel with high wear resistance. The morphology, structure and composition were analyzed using scanning electron microscopy (SEM), X-ray diffraction (XRD) and energy dispersive spectroscopy (EDS); wear mechanism was also discussed. Tribo-oxide layer was found to form on worn surfaces to reduce wear under low loads, but appear inside the matrix to increase wear under high loads. The tribo-oxides were mainly consisted of Fe3O4 and Fe2O3, FeO only appeared under a high load. Oxidative mild wear, transition of mild-severe wear in oxidative wear and extrusive wear took turns to operate with increasing the load. The wear resistance strongly depended on the selection of heat treatment processes or microstructures. It was found that bainite presented a better wear resistance than martensite plus bainite duplex structure, martensite structure was of the poorest wear resistance. The wear resistance increased with increasing austenizing temperature in the range of 920 to 1120 ℃, then decreased at up to 1220 ℃. As for tempering temperature and microstructure, the wear resistance increased in following order: 700 ℃ (tempered sorbite), 200 ℃ (tempered martensite), 440 to 650 ℃ (tempered troostite). An appropriate combination of hardness, toughness, microstructural thermal stability was required for a good wear resistance in high-temperature wear. The optimized heat treatment process was suggested for the cast hot-forging steel to be austenized at 1020 to 1120 ℃, quenched in oil, then tempered at 440 to 650 ℃ for 2 h. 相似文献
5.
The effects of solution and aging treatment on microstructure and mechanical properties of 10Ni2Cr2MnCuMoVAl plastic mold steel were experimentally studied. The results show that the dominant microstructure of 10Ni2Cr2MnCuMoVAl steel after solid solution treatment is lath martensite, and higher solution temperature results to larger width of martensite, while the highest value of hardness could be obtained after solution treatment at 890??. After aging, the microstructure consists of lath martensite, granular bainite and carbides. For steel aged at 460-520??, the strength of the material gradually increased with higher aging temperature, while the toughness decreased gradually. When the temperature exceeded 520??, higher temperature led to decreased hardness and increased toughness. Compared the mechanical properties of steel aged at 540?? for different time, the test steel reached the peak of mechanical properties at 8h. By comparing the mechanical properties of the test steels after different aging treatments, the optimized heat treatment process of 10Ni2Cr2MnCuMoVAl steel is solution treatment at 880?? for 2h with air cooling and tempering temperature at 540?? for 4h with air cooling. 相似文献
6.
09CuPTi系耐候钢组织性能及耐腐蚀行为 总被引:2,自引:0,他引:2
在热连轧生产线上采用两阶段轧制生产了09CuPTi系耐候钢,研究了轧制工艺参数对耐候钢板微观组织和力学性能的影响规律。结果表明,3种工艺试验钢的显微组织均为针状铁素体和贝氏体。当终冷温度为530℃冷却速度为25℃/s时,组织以更细小均匀的板条贝氏体为主,屈服强度及抗拉强度分别为617MPa和702MPa,韧脆性转变温度较低,具有良好的强韧性。对轧后钢板进行了耐腐蚀试验,研究了09CuPTi-Nb钢工艺B成品和参考钢在模拟工业大气环境下的腐蚀演化行为。结果表明,在腐蚀初期腐蚀速度随干湿循环次数的增加而增大,在后期腐蚀速度逐渐降低,09CuPTi-Nb钢的腐蚀速率与SPA-H钢相当,但低于Q345钢。09CuPTi-Nb钢锈层分为内外两层,内锈层致密主要由α-FeOOH和少量γ-Fe2O3组成,Q345钢锈层主要由α-FeOOH、γ-Fe2O3和Fe3O4组成。电化学试验表明,腐蚀产物促进阴极过程,抑制阳极过程。 相似文献
7.
对07MnCrMoR水电钢板的淬透性曲线进行了测定,利用淬火机和热处理炉对100 mm厚试验钢板进行了淬火和回火试验,并对试验钢进行了组织观察和力学性能测定。结果表明,随着试验钢距水冷端的距离增大,淬火组织由马氏体转变为粒状贝氏体,距离端部50 mm处转变为铁素体和粒状贝氏体的混合组织。试验钢板利用淬火机淬火后得到板条贝氏体+粒状贝氏体+先共析铁素体,回火后转变为铁素体+粒状贝氏体,同时大量的碳化物在铁素体基体和晶界处析出。试验钢最合理的热处理工艺为930℃ 30min水冷淬火,660℃ 60min空冷回火。 相似文献
8.
利用Formastor-F淬火膨胀仪热模拟和VL2000DX-SVF17SP高温激光共聚焦显微镜观察,研究了U25CrNi低碳贝氏体钢轨(/%:0.25C,1.73Si,1.69Mn,0.012P,0.002S,1.40Cr,0.57]Ni,0.49Mo,0.06V)从950℃以不同冷却速度连续冷却后的膨胀曲线和金相组织。结果表明,低冷速下(0.2℃/s),实验钢组织主要为贝氏体;随冷却速度增大至1℃/s,实验钢组织逐渐过渡为贝氏体和马氏体,且贝氏体板条尺寸随冷速增大而逐渐减小;当冷速达到2℃/s时,冷却过程中基本只发生马氏体相变,实验钢硬度随冷速增大而逐渐增大。 相似文献
9.
Recent years have been marked by considerable increase in the use of high-strength steel—especially martensitic and bainitic steel—for the manufacture of key industrial components and structures. The high strength depends on strain hardening of the steel. It is important to understand the strain hardening of steel of different structural classes with active plastic deformation, in order to ensure specified structural and phase states and mechanical properties. In the present work, by transmission electron-diffraction microscopy, the evolution of the structure, the phase composition, and the state of the defect substructure is compared for steel samples with martensite and bainite structure in active plastic deformation to failure. After austenitization at 950°C (1.5 h) and subsequent quenching in oil (for 38KhN3MFA steel) and cooling in air (for 30Kh2N2MFA steel), multiphase structure (α phase, γ phase, and cementite) based on packet martensite (38KhN3MFA steel) and lower bainite (30Kh2N2MFA steel) is formed. Quantitative results for the structural parameters of steel in plastic deformation permit analysis of the distribution of the carbon atoms in the structure of the deformed steel. The points of localization of carbon atoms in the martensite (quenched 38KhN3MFA steel) and bainite (air-cooled 30Kh2N2MFA steel) are identified. Deformation of the steel is found to be accompanied by the destruction of cementite particles. For quenched martensitic steel, the total quantity of carbon atoms in the solid solution based on α and γ iron is reduced, while their content at structural defects is increased. The redistribution of carbon atoms in the bainitic steel with increase in the strain involves the increase in the quantity of carbon atoms in the α iron, defects in the crystalline structure, and cementite at the intraphase boundaries; and the decrease in the content of carbon atoms in the cementite particles within the bainite plates and the γ iron. 相似文献