2024年, 第31卷, 第04期　刊出日期：2024-04-25

  

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  Review on regulation of MnS in non-quenched and tempered steel

  Guo-xing Qiu, Qing Du, Feng Lu, De-jun Miao, Yong-kun Yang, Xiao-ming Li

  钢铁研究学报(英文版). 2024, 31(04): 779-789.
  https://doi.org/10.1007s42243-023-01146-6

  摘要 ( )   可视化   收藏

  An overview of the current research status and control methods of MnS in non-quenched and tempered steel was provided. As a low-melting plastic inclusion, the morphology and distribution of MnS were influenced by various production processes. Therefore, control of MnS is a systematic problem that must be integrated into the entire production process. Based on the production process, the factors affecting the morphology and distribution of MnS in steel were introduced. The effects of oxygen activity, manganese, sulfur, and some alloys on MnS inclusion precipitation were summarized, mainly including MnS modification treatment and oxygen–sulfide composite precipitation control. It is believed that MnS precipitates during the solidification process of steel, and controlling the solidification cooling rate could effectively regulate the size and morphology of MnS, avoiding the precipitation of II-MnS. Additionally, by changing the deformation rate, deformation amount, deformation temperature during the hot deformation process, and heating time and temperature during heat treatment, the distribution and morphology of MnS could be improved. Through the fine control of the above process parameters, the number of II-MnS in steel could be effectively reduced, and their morphology could be improved, thereby enhancing the performance of non-quenched and tempered steel and promoting its wider application. Furthermore, applying laboratory research results to industrial production is an important direction for future research efforts in this field.
论著
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  Ferrite features in simulated transition zone of EH36 shipbuilding steel submerged arc welded by CaF2–SiO2–MnO fluxes

  Ming Zhong, Dong Hu, Da-ming Guo, Somnath Basu, Cong Wang

  钢铁研究学报(英文版). 2024, 31(04): 790-796.
  https://doi.org/10.1007s42243-023-01162-6

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  Ferrite features in the simulated transition zone welded with CaF₂–SiO₂–MnO fluxes containing various MnO contents have been investigated. Confocal laser scanning microscopy has been applied to simulate the thermal cycling of the transition zone and the phase transformations during cooling have been in-situ observed. It has been found that the appearance temperature for ferrite side plate decreases with increasing Mn content in the weld metals caused by MnO content increasing. Meanwhile, growth rates for both ferrite side plate and acicular ferrite are significantly enhanced with a higher Mn content of weld metal. Furthermore, from the statistical fractions of salient microstructures, for all samples, the acicular ferrite, grain boundary ferrite, and polygonal ferrite take over more than 90%. It has also been demonstrated that with the increase in Mn content, the ferrite side plate fraction increases slightly from 5% to 10% and the acicular ferrite fraction shows a tendency of first increasing and then decreasing, which experiences the maximum with the flux containing 30 wt.% MnO. This phenomenon is believed to be controlled by the O and Mn contents in weld metals synergistically.
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  Effect of alumina occurrence form on metallurgical properties of hematite and magnetite pellets

  Jian Pan, Chen-mei Tang, Cong-cong Yang, De-qing Zhu, Zheng-qi Guo, Wei-qun Huang

  钢铁研究学报(英文版). 2024, 31(04): 797-809.
  https://doi.org/10.1007s42243-023-01066-5

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  The effect of alumina occurrence form on the metallurgical properties of both hematite and magnetite pellets was investigated at the same Al₂O₃ level of 2 wt.%, including reduction index (RI), low-temperature reduction disintegration index (RDI), reduction swelling index (RSI), and high-temperature softening–dripping performance. The mineralogy of fired pellets was also studied to reveal the influence of alumina occurrence form on the phase composition and microstructure. From the results, the alumina occurrence form presents tremendous impacts on the metallurgical performance of both magnetite and hematite pellets. Addition of all alumina occurrence forms contributes to inferior reducibility of pellets, especially in the case of gibbsite for magnetite pellets with a RI of 58.4% and kaolinite for hematite pellets with a RI of 56.8%. However, addition of all alumina occurrence forms improves the RDI of magnetite pellets, while there is no significant difference among various alumina occurrence forms. In contrast, alumina occurrence forms have little influence on the RDI of hematite pellets. The presence of free alumina, gibbsite, and kaolinite tends to improve the RSI of hematite and magnetite pellets, whereas hercynite gives the opposite trend with a RSI of 25.6%. For softening–dripping performance of magnetite pellets, all alumina occurrence forms contribute to narrower softening–melting interval. Meanwhile, alumina, gibbsite, and kaolinite give narrower softening–dripping interval, at 229, 217, and 88 °C, respectively, whereas addition of hercynite results in the largest melting range at 276 °C due to its high melting point. Regarding hematite pellets, free alumina, gibbsite, and hercynite tend to enlarge melting range, whereas kaolinite contributes to lower dripping temperature of 1148 °C and narrow softening–dripping interval of 88 °C due to the formation of a greater amount of slag phase at high temperatures.
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  O2 adsorption on Fe3O4 (110) surface and effect of gangue element Al doping: combined study of binding experiment and ab initio molecular dynamics

  Zheng-jian Liu, Hui-qing Jiang, Yao-zu Wang, Jian-liang Zhang, Hong-mei Qiao, An-yang Zheng, Fang-yu Guo

  钢铁研究学报(英文版). 2024, 31(04): 810-827.
  https://doi.org/10.1007s42243-023-01111-3

  摘要 ( )   可视化   收藏

  At high temperature, the chemical reaction mechanism at the interface of magnetite and the influence mechanism of gangue element Al on the oxidation performance of magnetite are not clear. In addition, due to the limitation of existing experimental equipment, it is difficult to clarify the interface reaction mechanism in the oxidation process and the influence mechanism of Al on the surface oxidation reaction of Fe₃O₄ at an atomic scale at high temperature. The surface oxidation reaction mechanism of magnetite and the influence mechanism of Al on the oxidation of magnetite were studied by experiments and AIMD (ab initio molecular dynamics). The experimental results show that the existence of Al₂O₃ will reduce the initial oxidation temperature and comprehensive oxidation performance of magnetite. The AIMD results show that aluminum can accelerate the interface reaction rate of Fe₃O₄ in the high-temperature oxidation atmosphere, but the strong Al–O binding ability is not conducive to the transfer of O atoms in the oxidation process.
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  Volume of fluid simulation of single argon bubble dynamics in liquid steel under RH vacuum conditions

  Gu-jun Chen, Sheng-ping He

  钢铁研究学报(英文版). 2024, 31(04): 828-837.
  https://doi.org/10.1007s42243-023-01137-7

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  Single argon bubble dynamics in liquid steel under Ruhrstahl–Heraeus (RH) vacuum conditions were simulated using the volume of fluid method, and the ideal gas law was used to consider bubble growth due to heat transfer and pressure drop. Additional simulation with a constant bubble density was also performed to validate the numerical method, and the predicted terminal bubble shape and velocity were found to agree with those presented in the Grace diagram and calculated by drag correlation, respectively. The simulation results under RH conditions indicate that the terminal bubble shape and velocity cannot be reached. The primary bubble growth occurs within a rising distance of 0.3 m owing to heating by the high-temperature liquid steel; subsequently, the bubble continues to grow under equilibrium with the hydrostatic pressure. When the initial diameter is 8–32 mm, the bubble diameter and rising velocity near the liquid surface are 80–200 mm and 0.5–0.8 m/s, respectively. The bubble rises rectilinearly with an axisymmetric shape, and the shape evolution history includes an initial sphere, (dimpled) ellipsoid, and spherical cap with satellite bubbles.
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  Effect of Al content in molten steel on interaction between MgO–C refractory and SPHC steel

  Fu-bin Gao, Fu-ming Wang, Xiang Zhang, Tian-yu Du, Xin-hua Wang

  钢铁研究学报(英文版). 2024, 31(04): 838-848.
  https://doi.org/10.1007s42243-023-01107-z

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  The effect of Al content in molten steel on the interaction between SPHC steel (0.005–0.068 wt.% Als and 19 9 10-4– 58 9 10-4 wt.% O) and MgO–C refractory (11.63 wt.% C) was investigated. Non-metallic inclusions in the steel were examined at various periods (0, 5, 15, 30, 45, and 60 min) as well as the MgO–C interface after 60 min of corrosion at 1600 °C. The results show that when MgO–C refractory comes into contact with SPHC steel, the refractory interface consists of three layers arranged from the innermost to the outermost, including the original refractory layer, the dense MgO layer, and the iron infiltration layer. The carbon in the MgO–C refractories and the Al content in the molten steel undergo a reaction with the MgO in the refractories, resulting in an increase in Mg concentration in the steel. Increasing Al content in the molten steel from 0.005 to 0.068 wt.% causes a spinel layer to appear at the interface, and the disappearance time of Al2O3 inclusions in the steel decreases from 60 to 30 min, while the average MgO content in inclusions increases. Therefore, controlling the Al content in the molten steel and the smelting duration can help regulate the formation of spinel inclusions in the steel.
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  Effect of MgO–Cr₂O₃ and MgO–MgAl₂O₄-based refractories on refractory–steel interface reaction and cleanliness of pipeline steel

  Guang-mei Yang, Cheng Yuan, Chang Liu, Qiang Wang, Guang-qiang Li, Yong-shun Zou, Ao Huang

  钢铁研究学报(英文版). 2024, 31(04): 849-860.
  https://doi.org/10.1007s42243-023-01043-y

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  The interaction of MgO–MgAl₂O₄-based and MgO–Cr₂O₃-based refractories with X70 molten steel was studied by immersion experiments at 1560 °C. The effects of immersion time (30 and 60 min) on the contents of total oxygen (TO), Al, Nb, Si, Mn, and Cr as well as the composition, number density, and size distribution of inclusions in the molten steel were investigated. The influence of the penetration and erosion degree of the molten steel to the refractory on the steel–refractory interface layer was analyzed. The results show that, at 1560 °C, the MgO–MgAl₂O₄-based refractory can better control the contents of TO and the composition of molten steel compared with the MgO–Cr₂O₃-based refractory. The TO content is only 16 × 10^-4 wt.% in the molten steel after reacted with the MgO–MgAl₂O₄-based refractory at the end point of refining, accounting for 11.5% of that reacted with the MgO–Cr₂O₃-based refractory (139 × 10^-4 wt.%). The number density of inclusions is only 14 mm^-2, and the average size of inclusions is only 1.31 μm, with the largest proportion of inclusions in 1–2 μm (70%). The Al₂O₃–MnS–CaO complex inclusions in the original steel changed to complex inclusions dominated by Cr–Nb–Mn–S–O and MgO[1]Al₂O₃, corresponding to the MgO–Cr₂O₃-based and MgO–MgAl₂O₄-based refractories, respectively. TheMgO[1]Al₂O₃ layer was formed at the reaction interface betweenMgO–MgAl₂O₄-based refractory and molten steel, which is helpful to restrict the erosion of refractories and the pollution of molten steel. The damage mechanism of the MgO–Cr₂O₃-based refractory is mainly permeation and chemical reaction, while the damage of the MgO–MgAl₂O₄-based refractory is mainly scouring erosion.
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  Dissolution kinetics and reaction mechanism of Al2O3 in molten CaF2–CaO–Al2O3 slag

  Yao-xin Du, Yan-wu Dong, Zhou-hua Jiang, Ganna Stovpchenko, Yu-shuo Li, Jun Huang, Xin-wei Wang, Yu-xiao Liu

  钢铁研究学报(英文版). 2024, 31(04): 861-869.
  https://doi.org/10.1007s42243-023-01112-2

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  The dissolution behavior of Al2O3 in molten CaF2–CaO–Al2O3 slag, a basic slag system of electroslag remelting process, was investigated by rotating cylinder method using corundum rods to simulate Al2O3 inclusions in steel. The experimental results show that the dissolution rate of Al2O3 rods in CaF2–CaO–Al2O3 slag increases with the increase in rotating speed and temperature, and the rate-controlling step is the mass transfer in the slag. The dissolution rate of Al2O3 in CaF2–CaO– Al2O3 slag increases with the increase in the ratio of CaO to Al2O3, which is due to the increase in dissolution driving force and the decrease in slag viscosity. The apparent activation energy of the mass transfer of Al2O3 in slag C is calculated to be 222.86 kJ mol−1. During the dissolution of Al2O3 inclusions in the slag, it reacts with F− in liquid slag at first, then reacts with CaO to form the intermediate compounds of xCaO–yAl2O3 system, and finally dissolves in molten slag. The dissolution rate of Al2O3 inclusions in CaF2–CaO–Al2O3 slag for electroslag remelting is positively correlated with the ratio of the dissolution driving force and slag viscosity, and the correlation coefficient is 2.487×10−11.
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  Effect of Cr2O3 on properties of CaO–SiO2–FetO–MgO system and dissolution behavior of lime

  Shan-nan Li, Jian-li Li, Yue Yu, Hang-yu Zhu

  钢铁研究学报(英文版). 2024, 31(04): 870-881.
  https://doi.org/10.1007s42243-023-01121-1

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  The productivity of the chrome-containing semi-steel converter smelting process is directly affected by the slag-forming speed during the converter preliminary stage. The effects of Cr2O3 content on the physicochemical properties of the CaO– SiO2–FetO–MgO system, such as melting temperature, solidification behavior, mineral composition, and lime dissolution rate, were studied. The results showed that the slag was an amorphous phase at 1500 °C. When Cr2O3 was added, Ca(Fe,Mg)Si2O6 and spinel were formed in the slag. With the increase in Cr2O3 content, the amount of spinel precipitation increased, and the dendritic Fe3O4 crystal gradually changed into the granular (Fe,Mg)(Fe,Cr)2O4 crystal. As the Cr2O3 content increased from 0 to 2.91 wt.%, the melting temperature of the slag rose, and the melting range of the slag expanded slightly, but the lime dissolution rate did not change. When the Cr2O3 content further increased to 9.09 wt.%, the melting temperature continued to rise, the melting range rapidly expanded, and the lime dissolution rate decreased.
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  A new integrated model of deformation resistance and its application in prediction of rolling force of a thick plate

  Shun-hu Zhang, Yan Li, Li-zhi Che, Wen-hao Tian

  钢铁研究学报(英文版). 2024, 31(04): 882-893.
  https://doi.org/10.1007s42243-023-01084-3

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  The prediction accuracy of existing models of the rolling force of a thick plate is always very low. To address this problem, a high-precision genetic algorithm–backpropagation network (GA–BP) model of deformation resistance was built, and its integration with the traditional fitted model was further established. Then, a novel rolling force model was obtained by embedding the integration model of deformation resistance in the original model of rolling force. According to this research idea, the industrial data are normalized at first. On this basis, the interactions among the process parameters were disclosed through the variance analysis, and then described by various virtual factors. These factors are set as part of input parameters. Then, the optimal structure of the GA–BP model of deformation resistance was determined and an integration model of deformation resistance was built. Finally, a novel rolling force model is obtained by substituting the traditional fitted deformation resistance into the Sims model with the integration model of the deformation resistance. The results prove that the introduction of virtual factors can increase the hit rate of ± 5% from 75.8% to 78% and can reduce the root mean square error from 4.72% to 4.48%. Besides, it is found that the mean relative error of the traditional fitted deformation resistance is 0.142, while that of the modified deformation resistance is only 0.03. In addition, the mean relative error in the original rolling force model is 0.145, while that of the present model is only 0.03.
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  Influence of friction-lubrication characteristics varying with rolling speed on instability of chatter and slip in cold tandem rolling process

  Yan-li Xin, Zhi-ying Gao, Bo Tian, Qing-dong Zhang

  钢铁研究学报(英文版). 2024, 31(04): 894-908.
  https://doi.org/10.1007s42243-023-01047-8

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  In the high-speed cold tandem rolling process of thin plate, chatter or slip instability gives rise to the deterioration of equipment and product quality. Macroscopic instability behavior is closely related to interfacial friction-lubrication condition which is generally characterized by the friction coefficient. However, with higher and higher speed requirements, the commonly used model of friction coefficient is no longer applicable and accurate. A novel approach is suggested to calculate the speed-dependent friction coefficient, in which the viscosity–pressure–temperature effects of the lubricant, surface roughness states of work rolls and rolled piece are comprehensively involved and the mixed film lubrication theory is applied. Subsequently, the influences of friction coefficient on the instability of slip and chatter are investigated for a five-stand cold tandem rolling mill. On one side, the critical friction coefficient for each stand is determined by calculating the corresponding slip factor; on the other hand, the friction coefficient varying with rolling speed is combined with the model of theoretical critical rolling speed presented under constant friction coefficient, so that the speed threshold is determined. Furthermore, the stable and unstable regions corresponding to the rear three stands are individually discussed, and the technical strategies are proposed to suppress both slip and chatter frequently occurring in the actual rolling process.
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  Microstructure recognition of steels by machine learning based on visual attention mechanism

  Xing-yu Chen, Lin Cheng, Cheng-yang Hu, Yu-peng Zhang, Kai-ming Wu

  钢铁研究学报(英文版). 2024, 31(04): 909-923.
  https://doi.org/10.1007s42243-023-01031-2

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  U-Net has achieved good performance with the small-scale datasets through skip connections to merge the features of the low-level layers and high-level layers and has been widely utilized in biomedical image segmentation as well as recent microstructure image segregation of the materials. Three representative visual attention mechanism modules, named as squeeze-and-excitation networks, convolutional block attention module, and extended calibration algorithm, were introduced into the traditional U-Net architecture to further improve the prediction accuracy. It is found that compared with the original U-Net architecture, the evaluation index of the improved U-Net architecture has been significantly improved for the microstructure segmentation of the steels with the ferrite/martensite composite microstructure and pearlite/ferrite composite microstructure and the complex martensite/austenite island/bainite microstructure, which demonstrates the advantages of the utilization of the visual attention mechanism in the microstructure segregation. The reasons for the accuracy improvement were discussed based on the feature maps analysis.
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  Influence of powder oxidation on powder properties and formability in H13 hot-work steels processed by electron beam melting

  Wei Liu, Yan Wang, Li-xiong Han, Ying-kang Wei, Hui-ping Tang, Shi-feng Liu

  钢铁研究学报(英文版). 2024, 31(04): 924-932.
  https://doi.org/10.1007s42243-023-01049-6

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  The oxygen content of metal powder is decisive for the recyclability of powder. The research on the effect of oxygen content on powder properties and material formability has practical significance for economical production with additive manufacturing while preventing the waste of resources. Here, we deliberately oxidized the powder by baking at high temperature to increase the oxygen content in the powder and gave the calculation method of the oxygen content in the powder oxidation film. The majority of oxygen element was found in the oxide particles in the powder and the oxide film on the powder surface, which did affect the flowability of the powder. It is worth noting that the increase in the oxygen content does not change the phase of H13 steel, but it can promote the molten pool flow and obtain a smoother surface. The increase in the oxygen content in the powder is not the decisive factor for the formability and defects of the printed samples. It is the combined effect of the powder deformation, the increase in the oxygen content, and the impurity pollution after repeated use, which leads to the limitation of repeated utilization of the powder.
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  Effects of rare earth elements on inclusions, microstructure and impact toughness of spring steel

  Chun-lei Hao, Chao-yun Yang, Peng Liu, Yi-kun Luan, Bao-guang Sang

  钢铁研究学报(英文版). 2024, 31(04): 933-944.
  https://doi.org/10.1007s42243-023-01055-8

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  Spring steel is an indispensable basic part manufacturing material in mechanical equipment, which is widely used in transportation tools such as automobiles, railways, construction machinery and other industries. The effects of rare earth (RE) on inclusions, microstructure, carbides and impact toughness of 50CrV spring steel were studied by means of optical microscope, scanning electron microscope, transmission electron microscope and impact tester. The results show that the addition of rare earth can modify the main MnS and Al2O3 inclusions in steel to form spherical or near-spherical rare earth inclusions, and the size of inclusions is significantly reduced. In the quenched structure, the size of martensite slab becomes smaller and the structure is refined. After tempering, the carbide changes from sheet to ellipse, which makes it easier for spring steel to form stress concentration cracks under stress. VC becomes finer and more dispersed, which leads to better pinning of grain boundaries and smaller grain sizes. The impact toughness of 50CrV-RE spring steel increased from 21 to 41 J by 95% due to the improvement of inclusions, microstructure and carbides by rare earth. It is possible to improve the strength and toughness of spring steel for the improvement of railway running speed and the development of vehicle lightweight in China.
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  Effect of heat treatment on microstructure and mechanical properties of selective laser-melted PH13-8Mo stainless steel

  Yuan Zhang, Xiang Liu, Chang-jun Wang, Chang Liu

  钢铁研究学报(英文版). 2024, 31(04): 945-955.
  https://doi.org/10.1007s42243-023-00969-7

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  PH13-8Mo stainless steel powder with high sphericity and well fluidity was prepared by the plasma rotating electrode process. The formed parts with ultra-high purity were manufactured by selective laser melting. The tensile and impact mechanical properties of the printed parts under three heat treatment regimes were compared to those without heat treatment. The microstructure, grain orientation and phase composition were characterized by electron-backscatter diffraction, X-ray diffraction and transmission electron microscopy. The characterization results reveal that the addition of heat treatment makes the grains enlarge, and after different heat treatments, the average grain size from 1.51 lm in the printed state increases to 2.78, 3.09 and 2.06 lm, respectively. The formed parts are mainly composed of martensite and retained austenite. Moreover, the NiAl and M23C6 precipitates form, which are the major strengthening phases of PH13- 8Mo stainless steel. The optimal heat treatment process is 925 °C 9 1 h water cooling (WC) ? 0 °C 9 2 h air cooling (AC) ? 540 °C 9 4 h AC. Using this heat treatment process, PH13-8Mo formed parts have the optimal comprehensive mechanical properties: the tensile strength, yield strength and impact energy KU2 are 1492 MPa, 1432 MPa and 63 J, respectively. The strengthening and toughening via heat treatment are mainly attributed to dislocation strengthening, the formation of NiAl and M23C6 precipitates and the change of volume fraction of the retained austenite.
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  Solidification behaviour and hot cracking susceptibility of a novel Ni-based superalloy

  Yue Chen, Shao-min Lv, Xing-fei Xie, Xiao-can Wen, Jing-long Qu, Jin-hui Du

  钢铁研究学报(英文版). 2024, 31(04): 956-966.
  https://doi.org/10.1007s42243-024-01190-w

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  A novel Ni-based superalloy GH4151, with a c0 volume fraction of about 55% and a service temperature capability up to 800 °C, was investigated. Due to the different cooling conditions of various regions during the solidification of ingots, significant cooling rate variations may lead to the occurrence of hot cracking. Conventional scanning laser microscope was utilised to investigate the solidification process and phase precipitation behaviour of the GH4151 under wide range cooling rates. The characteristics of L ? c transformation were analysed, and the growth rates of c at each stage were calculated. The segregation behaviour was predicted using the Scheil equation, and the predicted results match well with the experimental results. The sensitivity coefficient for hot cracking was modified, and cracking sensitivity coefficient values for the alloy under different cooling rates were computed, revealing that the alloy is most susceptible to hot cracking at 10 °C/min cooling rate. Therefore, controlling the cooling rate can reduce the possibility of hot cracking in ingot.
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  Mechanical performance of 22SiMn2TiB steel welded with low transformation- temperature filler wire and stainless steel filler wire

  Zi-dong Lin, Kai-jie Song, Zhen Sun, Zi-qian Zhu, Xue-feng Zhao, Constantinos Goulas, Wei Ya, Xing-hua Yu

  钢铁研究学报(英文版). 2024, 31(04): 967-981.
  https://doi.org/10.1007s42243-023-01098-x

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  TX-80 low-transformation-temperature (LTT) welding wire was used to replace the traditional ER 307Si welding wire to realize the connection of 22SiMn2TiB armor steel in manual overlay welding. The previously existing issues, such as welding cracks, large welding deformation, and severe welding residual stress, were solved to ensure good strength and ductility requirements. In particular, with the same welding conditions, TX-80 LTT wire eliminates welding cracks. It reduces the welding deformation no matter the base pretreatment of pre-setting angle or no pre-setting angle. By comparison, it was found that the microstructure at the TX-80 weld is mainly composed of martensite and a small amount of retained austenite. In contrast, the microstructure of the ER 307Si weld consists of a large amount of austenite and a small amount of skeleton-like ferrite. The variation trend of residual stress and microhardness from the weld to the base were investigated and comparedwith the mechanical properties of base materials. The TX-80 and the ER 307Si tensile samples elongation is 6.76% and 6.01%, while the ultimate tensile strengths are 877 and 667 MPa, respectively. The average impact toughness at room temperature of the ER 307Si weld is 143.9 J/cm2, much higher than that of the TX-80 weld, which is only 36.7 J/cm2. The relationship between impact and tensile properties with microstructure species and distribution was established. In addition, the fracture surface of the tensile and the impact samples was observed and analyzed. Deeper dimples, fewer pores, larger radiation zone, and shear lips of TX-80 samples indicate better tensile ductility and worse impact toughness than those of ER 307Si weld.
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  Electronic-scale assessment of high-temperature oxidation mechanisms in a novel Fe-based alloy

  Wei-di Luo, Ting-ping Hou, Xuan Liang, Dong Zhang, Heng-fu Lin, Yu Li, Tian-liang Zhao, Cheng-yang Hu, Serhii Yershov, Kai-ming Wu

  钢铁研究学报(英文版). 2024, 31(04): 982-997.
  https://doi.org/10.1007s42243-023-01125-x

  摘要 ( )   可视化   收藏

  The development of alloys with high antioxidation performance is limited by the ambiguous details of the oxidation mechanism. Here, based on the structures of internal oxides detected by high-resolution transmission electron microscopy, a hybrid method combining first-principles calculation, climb image nudged elastic band method and quasi-harmonic Debye model has been implemented to explain the oxidation mechanism with an emphasis on the origin of delamination and cracking. The results showed that the delamination of oxides corresponds to the acceleration of diffusion of Cr element caused by lamellar structures. The reduction in the cracking occurrence at high temperature mainly results from the smaller bulk modulus of oxides. Furthermore, the stronger chemical bonds promoted by lamellar structures also correspond to the higher cracking resistance.
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  Root cause of corrosion failure of tin coating on wire clamp in marine atmosphere

  Zhen Zhong, Wang-yan Lv, Teng-yuan Liu, Yi Xie, Yang Yang, Zhen-zhu Wang, Deng-ke Li, Xiao-bo Li, Tang-qing Wu

  钢铁研究学报(英文版). 2024, 31(04): 998-1014.
  https://doi.org/10.1007s42243-023-01122-0

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  The failure cause of a tinned copper wire clamp in marine atmosphere was studied systematically by X-ray photoelectron spectroscopy, scanning electron microscopy with energy dispersive spectroscopy and electrochemical measurements. The main components of the green rust on the surface of the damaged wire clamp are SnO2, CuO, Cu2Cl(OH)3 and CuCO3(OH)2. Much of green rust distributes at the platform edge along the axial direction on the crimp connection, and severe corrosion and corrosion pits occur at the platform edge zone along the axial direction. The enriching Cl- at the marine atmosphere and the existing O2 in air collectively enhance the corrosion process of the tin coating and the copper matrix. Finite element model results show that the residual stress and strain of the tin coating are the largest at the platform edge along the axial direction on the crimp connection, and the corresponding electrode potential of the tin coating at this zone drops significantly. The above results indicate that the residual strain increases the driving force of the corrosion electrochemical reactions and accelerates the corrosion rate and the pit corrosion of the tin coating at this zone.
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  CO2 corrosion of X80 steel welded joints under micro-turbulence induced by welding reinforcement height

  Xiao-hui Dou, Bin Li, Zong-hao He, Xin-wei Zhang, Da-lei Zhang, Yan Li

  钢铁研究学报(英文版). 2024, 31(04): 1015-1032.
  https://doi.org/10.1007s42243-023-01091-4

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  Corrosion failure accidents owing to flow erosion and pipeline corrosion frequently occur during transportation. The welding reinforcement height (WRH) can induce locally micro-turbulent flow field, which aggravates local corrosion of welded joints. A high wall shear stress (WSS) experimental setup was established to conduct the online electrochemical corrosion test. The influence of WRH sizes on local corrosion of welded joints was studied at different flow rates. The electrochemical signals of the local corrosion of X80 welded joints at different flow rates were monitored in real time using electrochemical impedance spectroscopy and wire beam microelectrode. In addition, the corrosion products composition and properties were analyzed. The results show that the micro-turbulent flow fields induced by the WRHs can enhance ion mass transfer near the welded joints. The corrosion products on the WRH surface also present different microscopic morphologies at different flow rates. In strong flow fields, the locally enhanced WSS can peel off the dense corrosion product partially, leading to the electrochemical distribution of large cathode and small anode, which accelerates the occurrence and development processes of the local corrosion of welded joints. The scientific guidelines for the corrosion protection of long-distance oil and gas pipelines can be potentially provided.