Effect of Cr/Mn segregation on pearlite–martensite banded structure of high carbon bearing steel

The effect of Cr/Mn segregation on the abnormal banded structure of high carbon bearing steel was studied by reheating and hot rolling.With the use of an optical microscope, scanning electron microscope, transmission electron microscope, and electron probe microanalyzer, the segregation characteristics of alloying elements in cast billet and their relationship with hot-rolled plate banded structure were revealed.The formation causes of an abnormal banded structure and the elimination methods were analyzed.Results indicate the serious positive segregation of C, Cr, and Mn alloy elements in the billet.Even distribution of Cr/Mn elements could not be achieved after 10 h of heat preservation at 1200℃, and the spacing of the element aggregation area increased, but the segregation index of alloy elements decreased.Obvious alloying element segregation characteristics are present in the banded structure of the hot-rolled plate.This distinct white band is composed of martensitic phases.The formation of this abnormal pearlite–martensite banded structure is due to the interaction between the undercooled austenite transformation behavior of hot-rolled metal and the segregation of its alloying elements.Under the air cooling after rolling, controlling the segregation index of alloy elements can reduce or eliminate the abnormal banded structure.

Spheroidization and Ostwald Growth of Carbide in Isothermal Process of Hot-Deformed High Carbon Chromium Cast Steel

In isothermal spheroidizing process,the spheroidization and growth of the carbide formed in hot-deformed high-carbon chromium cast steel at high temperature were investigated.The results showed that the spheroidizing growth of carbide proceeds in such a way that the bigger carbide particles swallow the smaller ones,and the short rhabdoid carbides dissolve and are spheroidized by itself.When the samples were held at 720℃ for more than 3 h,the spheroidization is not obvious.The feature of the process is the size increment and the amount decrement of carbide particles.The empirical equation for growth rate of carbides was obtained.The volume fraction of carbides keeps constant.The growth process agrees well with Ostwald Ripening Law.

Microstructure and Property of High Carbonic-Chromium Cast Steel with Different Hot Deformation Ratio

The microstructure and properties of high carbonic-chromium cast steel subjected to different hot deformation ratios were studied.The experimental results show that the microstructure and properties of high carbonic-chromium cast steel are obviously improved after hot deformation,and the best mechanical properties of the cast steel can be obtained under hot deformation ratio of 40 %-50 %,which leads to the morphology change of eutectic carbide and the precipitation of granular carbides.

Advanced manufacturing technologies of large martensitic stainless steel castings with ultra low carbon and high cleanliness

The key manufacturing technologies associated with composition, microstructure, mechanical properties, casting quality and key process control for large martensitic stainless steel castings are involved in this paper. The achievements fully satisfeid the technical requirements of the large 700 MW stainless steel hydraulic turbine runner for the Three Gorges Hydropower Station, and become the major technical support for the design and manufacture of the largest 700 MW hydraulic turbine generator unit in the world developed through our own efforts. The characteristics of a new high yield to tensile strength (R p0.2/R m ) ratio and high obdurability martensitic stainless steel with ultra low carbon and high cleanliness are also described. Over the next ten years, the large martensitic stainless steel castings and advanced manufacturing technologies will see a huge demand in clean energy industry such as nuclear power, hydraulic power at home and abroad. Therefore, the new high yield o tensile strength (R p0.2/R m ) ratio and high obdurability martensitic stainless steel materials, the fast and flexible manufacturing technologies of large size castings, and new environment friendly sustainable process will face new challenges and opportunities.

Intergranular corrosion behavior of high nitrogen austenitic stainless steel

The intergranular corrosion （IGC） behavior of high nitrogen austenitic stainless steel （HNSS） sensitization treated at 650-950℃ was investigated by the double loop electrochemical potentiodynamic reactivation （DL-EPR） method. The effects of the electrolytes, scan rate, sensitizing temperature on the susceptibility to IGC of HNSS were examined. The results show that the addi-tion of NaCl is an effective way to improve the formation of the cracking of a passive film in chromium-depleted zones during the reactivation scan. Decreasing the scan rate exhibits an obvious effect on the breakdown of the passive film. A solution with 2 mol/L H2SO4＋1 mol/L NaCl＋0.01 mol/L KSCN is suitable to check the susceptibility to IGC of HNSS at a sensitizing temperature of 650-950℃ at a suitable scan rate of 1.667 mV/s. Chromium depletion of HNSS is attributed to the precipitation of Cr2N which results in the susceptibility to IGC. The synergistic effect of Mo and N is suggested to play an important role in stabilizing the passive film to prevent the attack of IGC.

Development of ferritic stainless steel B445R with superior corrosion resistance for architectural applications

The dull-finish ferritic stainless steel （FSS） sheet B445R for architectural roofing has been developed by Baosteel. This steel product exhibits excellent corrosion resistance superior to that of SUS 316L with a lower cost. It can be easily formed into roofing panels by ordinary processes. Moreover,the thermal strain of it is less than SUS 316L because of its lower thermal expansion coefficient, and its reflectivity is lower due to the dull-finish treatment. All of these features make it capable of being used as architectural roofing materials in coastal regions.

Effects of rare earth elements on inclusions and impact toughness of high-carbon chromium bearing steel

High-carbon chromium bearing steels with different rare earth (RE) contents were prepared to investigate the effects of RE on inclusions and impact toughness by different techniques. The results showed that RE addition could modify irregular Al2O3 and MnS into regular RE inclusions. With the increase of RE content, the reaction sequence of RE and potential inclusion forming elements should be O, S, As, P and C successively. RE inclusions containing C might precipitate in molten steel and solid state, but the precipitation tem perature was significantly higher than that of carbides in high-carbon chromium bearing steel. For experim ental bearing steels, the volume fraction of inclusions increased steadily with the increase of RE content, but smaller and more dispersed inclusions could be obtained by 0.018% RE content compared with bearing steel without RE, whereas the continuous increase of RE content led to an increasing trend for inclusion size and a gradual deterioration for inclusion distribution. RE addition could improve the transverse impact toughness and isotropy of bearing steel, and for modified highcarbon chrom ium bearing steel by RE alloying, the increase of RE content continuously increased both transverse and longitudinal im pact toughness until excessive RE addition.

Microstructure, hardness and contact fatigue properties of X30N high nitrogen stainless bearing steel

Microstructure, hardness and fatigue properties of X30N high nitrogen stainless bearing steel were investigated. It was found that nitrogen addition could effectively reduce the amount and size of coarse carbides. The original austenite grain size was obviously refined. Additionally, more retained austenite was found in X30N steel after quenching at 1050 ℃, which could be reduced from about 30% to about 6% by cold treatment at - 73 ℃ and subsequent tempering, and thus, the ultimate hardness was increased up to about 61 HRC with reduction of austenite and precipitation of carbonitrides. Furthermore, the rolling contact fatigue lives of X30N steel ate superior to those of 440C steel, which was attributed to the enhanced hardness and a certain retained austenite in the high nitrogen steel.

Comparison of microstructure and property of high chromium bearing steel with and without nitrogen addition

Microstructure and property of bearing steel with and without nitrogen addition were investigated by microstructural observation and hardness measurement after different heat treatment processing. Based on the microstructural observation of both 9Cr18 steel and X90N steel, it was found that nitrogen addition could effectively reduce the amount and size of coarse carbides and also refine the original austenite grain size. Due to addition of nitrogen, more austenite phase was found in X90N steel than in 9Cr18 steel. The retained austenite of X90N steel after quenching at 1050℃ could be reduced from about 60% to about 7 9% by cold treatment at -73℃ and subsequent tempering, and thus finally increased the hardness up to 60 HRC after low temperature tempering and to 63 HRC after high temperature tempering. Furthermore, both the wear and corrosion resistance of X90N steel were found much more superior than those of 9Cr18 steel, which was attributed to the addition of nitrogen. It was proposed at last that nitrogen alloying into the high chromium bearing steel was a promising way not only to refine the size of both carbides and austenite, but also to achieve high hardness, high wear property and improved corrosion resistance of the stainless bearing steel.

Infuence of Mg on Thermoplasticity of High-Temperature Stainless Bearing Steel Cr_(14)Mo_4

Through the addition of appropriate amount of Mg （0.01-0.01 5 wt%） to the stainless bearing steel Cr14Mo4, the high-temperature thermoplasticity of steel was improved. The mechanism has been uncovered that the added Mg plays an important role in refining and uniforming the carbide precipitations in the steel. It has been found that the segregation of trace Mg is the key to improve the dispersed carbide. Moreover, considerable segregation of Mg in steel during annealing was evidenced by the theoretic analysis.

内置碳钢不锈钢管海洋混凝土柱轴压试验及承载力计算

为研究不锈钢管海洋混凝土柱及内配碳钢后的轴压力学性能,以型钢类型、螺旋筋间距、纵筋直径为变化参数,完成了10个试件的轴心受压静力加载试验。观察了试件的受力破坏全过程及形态,获取了轴向荷载-位移曲线及各钢材应变曲线,基于试验实测数据,就各变化参数对试件的轴压承载力、延性、耗能能力和损伤发展的影响规律进行了分析。结果表明:不同试件的破坏形态相似,均表现为不锈钢管局部屈曲压皱,混凝土斜向剪切破坏;内置碳钢可以提高试件的极限承载力、轴压延性和耗能能力,抑制试件的损伤发展;在增加相同用钢量的条件下,增加圆钢管含钢量对试件轴压性能提升幅度最大;基于“复合约束叠加法”推导计算公式所得承载力计算值与试验值吻合良好。

CFRP-不锈钢夹层管混凝土柱轴压试验及承载力计算方法

为了提升薄壁不锈钢结构的承载性能和耐久性,在不锈钢管内外壁粘贴碳纤维增强复合材料(Carbon Fiber-Reinforced Polymer,CFRP)复合约束海水海砂混凝土,制得一种CFRP-不锈钢夹层管海水海砂混凝土结构。以CFRP粘贴层数和方式为变化参数,对18个短柱试件进行了单调轴心受压试验,观察了试件的受力破坏过程及形态,获取了荷载-位移曲线和材料应变分布数据,分析了试件轴压力学性能的变化规律。结果表明:内外贴CFRP能有效地提高结构的承载能力和变形能力;无CFRP和内贴CFRP试件的破坏形态均为剪切破坏,但破坏形态会随着外贴CFRP层数的增加向腰鼓破坏转变;在相同粘贴方式下,试件的承载能力、变形能力和耗能能力随着CFRP层数的增加呈非线性提高;在相同粘贴层数下,内贴CFRP的力学性能提升效果优于外贴CFRP,粘贴1层和2层CFRP时,内贴试件的极限承载力相较于外贴试件能再提高5.6%和6.7%,同时内贴1层CFRP的试件的耗能能力与外贴2层CFRP的相当;应变分析显示,在试件破坏前,CFRP与不锈钢协同工作良好。文中最后基于极限平衡法,考虑不锈钢的应变硬化效应,提出了CFRP-不锈钢夹层管混凝土柱极限轴压承载力的计算公式,并收集了73个样本的数据进行验证,发现计算值与试验值较为吻合。

高碳铬轴承钢球化退火碳化物尺寸评级标准的对比讨论

本文对比分析制造业现行以下各标准关于高碳铬轴承钢碳化物尺寸规定:GB/T 18254-2016高碳铬轴承钢第5级别图退火组织,SEP 1520-1998钢中碳化物图谱系列显微检验法(斯凯孚公司D33标准总则采用同一标准),ASTM A892-09(2020)高碳轴承钢显微组织的定义和等级的标准导引及其附录金相图谱,舍弗勒公司轴承钢100Cr6球化退火显微组织标准(图谱)S 261010。对于球化退火碳化物尺寸评级,可见我国标准比国外标准级数少,且碳化物尺寸级差不均匀;我国企业通常要求第2级合格,碳化物尺寸偏大,并且显示偏聚程度较大和存在个别大颗粒;没有对超细球化退火组织碳化物级别的界定。需要结合我国轴承企业发展现状并参照国际先进标准,适当修订相关标准。

稀土Ce含量对GCr15SiMn轴承钢冲击性能的影响

制备了不同Ce加入量的GCr15SiMn轴承钢,并对其冲击性能的变化及影响因素进行分析。结果表明:钢中MnS和Al2O3夹杂物在适量Ce的作用下变为球形或椭球形且尺寸较小的稀土夹杂物;稀土夹杂物的种类和数量随Ce含量的增加而增加,Ce加入过量后,夹杂物出现聚合长大导致其尺寸变大且形貌不规则;随着Ce含量的增加,试样的冲击性能先升高后降低,当Ce含量为0.016%时,直径3μm以下小尺寸夹杂物占比最多,夹杂物分布最弥散,且试验钢冲击性能最佳,比不加Ce时提高了173.7%,Ce含量过高时反而降低冲击性能。

高速激光熔覆马氏体不锈钢涂层与电镀层性能对比与研究

为对比研究不同液压缸服役工况下高速激光熔覆涂层替代电镀硬铬层的可行性,分别制备了马氏体不锈钢熔覆层XG-1、XG-2和电镀硬铬涂层,开展了三种涂层组织、硬度、腐蚀性能及模拟不同工况(划伤磨损、干砂摩擦磨损、滑动摩擦磨损)下磨损性能测试,探讨了涂层失效行为及其应用工况。结果表明:XG-1、XG-2涂层微观组织致密且均匀,平均显微硬度为720.5 HV、653 HV;电镀硬铬涂层分布孔隙和裂纹等缺陷,自腐蚀电流密度为10.45μA/cm^(2),耐腐蚀性能最差;三种磨损形式下电镀硬铬涂层均发生了开裂及剥落,高速激光熔覆涂层表现出更优异的耐磨性能,适用于活塞杆易拉伤、外界富集硬质颗粒污染物、大侧向载荷等液压缸服役工况。

Si对铸态高碳铬轴承钢中渗碳体类型转变的影响机理

利用真空感应炉制备了四种不同Si(质量分数/%:0.29、0.42、0.71、1.50)的铸态高碳铬轴承钢,并采取非水溶液电解法萃取钢中碳化物。通过扫描电镜观察钢中碳化物的二维和三维形貌,采用X-射线衍射仪(XRD)对不同Si含量下碳化物的类型进行探究,并结合热力学和第一性原理计算明确Si含量影响渗碳体类型的本质机理。研究结果表明,不同Si含量的高碳铬轴承钢中都存在两种类型的碳化物,分别是片层状渗碳体((Fe_(1-X)Mn_(X))_(3)C)和晶界碳化物M23C6。随着w[Si]从0.29%增加到1.50%,M23C6晶界碳化物由连续粗大的棒状结构变为断续细小的点状结构,说明Si含量的增加对晶界碳化物的析出具有抑制效果。而Si含量的增加,降低了Mn在(Fe_(1-X)Mn_(X))_(3)C渗碳体中的占比,渗碳体类型的转变趋势为Fe_(1.8)Mn_(1.2)C向Fe_(3)Mn0C转变。可能的原因是,渗碳体生成析出过程,Si原子被外排到渗碳体周围形成富Si微区,阻碍基体中的Mn原子向渗碳体扩散,降低了Mn在基体中的活度以及扩散迁移能力,从而降低了Mn在渗碳体中的相对含量。

不同热处理方式对白色组织剥落的影响

研究了马氏体淬火、贝氏体淬火、碳氮共渗、渗碳4种不同热处理方式对白色组织剥落的影响,使用10%硫氰酸铵溶液对试样预充氢处理后进行疲劳试验,结果表明:试样中氢含量大于1.5×10^(-6)时,随氢含量的增加,试样发生剥落的时间相差不多;氢含量小于1.5×10^(-6)时,随氢含量的减少,发生剥落的时间增加;小于1.0×10^(-6)时,氢会失去促进白色组织剥落的作用;马氏体淬火未充氢与充氢试样的L_(10)寿命比为1:0.46,马氏体淬火、贝氏体淬火、碳氮共渗、渗碳充氢试样的L_(10)寿命比为1:1.19:2.17:5.76;渗碳热处理能够有效改善钢材白色组织剥落问题。

GCr15轴承钢夹杂物形成机理研究

为了掌握国内某大型钢企轴承钢夹杂物形成机理,通过热力学计算对GCr15轴承钢夹杂物开始析出温度进行了相应的分析研究。研究结果表明:钢中氧化物、Ca S夹杂的析出温度均远高于液相线1 727.85 K,可以在钢液中析出,而Mn S、氮化物夹杂只能在铸坯凝固冷却过程中析出。在铸坯凝固前沿,元素Mn、S的偏析度随着固相率的增大而增加,S比Mn偏析的更为严重,当凝固前沿固相率达到99.1%时,便会析出Mn S夹杂。此时,钢液中的w(Mn)为1.043%,w(S)为0.565%。同理,N、Ti、Nb、Al和V元素的偏析度随着固相率的增大而增加,偏析度最大的是N元素,其次为Ti、Nb、Al和V元素。在铸坯冷却凝固过程中,钢液中N元素优先与Ti结合,减少并抑制了细小AlN、Nb N和VN夹杂的析出。

高碳铬轴承钢的旋转弯曲疲劳性能

采用简支梁旋转弯曲疲劳试验机对SUJ2S1高碳铬轴承钢进行旋转弯曲疲劳性能测试,绘制了材料的疲劳极限升降图、疲劳强度-疲劳寿命曲线和存活率-疲劳强度-疲劳寿命曲线。采用场发射电子显微镜对材料发生疲劳断裂的原因进行分析。结果表明:高碳铬轴承钢的疲劳极限为458 MPa,存活率为90%时的疲劳极限为300 MPa;试验钢表面存在机械加工缺陷和Al_(2)O_(3)夹杂物,最终导致材料发生疲劳断裂现象。

GCr15轴承钢圆锥滚子理化性能研究

本研究旨在探索更大尺寸GCr15轴承钢圆锥滚子的理化性能,为轴承零件选材和扩大GCr15轴承钢应用提供参考。通过GCr15轴承钢圆锥滚子理化性能研究,有效直径35mm的圆锥滚子表层显微组织、表层硬度、心部显微组织均符合标准推荐要求,心部硬度低于标准推荐值59HRC的区域径向尺寸占比25.37%,轴向尺寸占比39.37%,其中低于淬硬值58HRC的区域径向尺寸占比12.11%,轴向尺寸占比23.36%。为满足标准推荐值要求,GCr15轴承钢圆锥滚子可选材应用尺寸到有效直径为26.12mm;为满足淬硬值需要,GCr15轴承钢圆锥滚子可选材应用尺寸到有效直径为30.76mm。在满足使用要求的前提下,用户和制造厂可协商确定更大尺寸的应用,以获得良好的性价比。