2024年, 第31卷, 第8期　刊出日期：2024-08-25

  

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  Refill friction stir spot welding (RFSSW): a review of processing, similar/dissimilar materials joining, mechanical properties and fracture mechanism

  Yun-qiang Zhao, Hao-kun Yang, Aloshyn Andriia, Hong-hang Lo, Jia-xin Li

  钢铁研究学报(英文版). 2024, 31(8): 1825-1839.
  https://doi.org/10.1007/s42243-024-01209-2

  摘要 ( )   可视化   收藏

  Refill friction stir spot welding (RFSSW) provides a novel method to join similar and/or dissimilar metallic materials without a key-hole in the center of the joint. Having the key-hole free characterization, the similar/dissimilar RFSSW joint exhibits remarkable and endurable characteristics, including high shear strength, long fatigue life, and strong corrosion resistance. In the meanwhile, as the key-hole free joint has different microstructures compared with conventional friction stir spot welding, thus the RFSSW joint shall possess different shear and fatigue fracture mechanisms, which needs further investigation. To explore the underlying failure mechanism, the similar/dissimilar metallic material joining parameters and pre-treatment, mechanical properties, as well as fracture mechanisms under this novel technology will be discussed. In details, the welding tool design, welding parameters setting, and the influence of processing on the lap shear and fatigue properties, as well as the corrosion resistance will be mainly discussed. Moreover, the roadmap of RFFSW is also discussed.
论著
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  Effect of temperature and reaction path interaction on fluidization reduction kinetics of iron ore powder

  Guo-min Zhu, Ming-wei Hu, An-nan Dou, Jin-yu Huang, Jing Ding, Qi-yan Xu

  钢铁研究学报(英文版). 2024, 31(8): 1840-1849.
  https://doi.org/10.1007/s42243-024-01182-w

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  Due to the instability of FeO at temperatures below 843 K, the fluidization reduction pathway of iron ore powder changes with the reduction temperature. Thus, the effect of temperature and reaction pathway interaction on the kinetics of fluidization reduction of iron ore powder under low-temperature conditions ranging from 783 to 903 K was investigated to describe the fluidization reduction rate of iron ore powder from three aspects: microstructure change, reaction limiting link, and apparent activation energy of the reaction, exploring their internal correlation. The experimental results revealed that in a temperature range of 783–813 K, the formation of a dense iron layer hindered the internal diffusion of reducing gas, resulting in relatively high gas diffusion resistance. In addition, due to the differences in limiting links and reaction pathways in the intermediate stage of reduction, the apparent activation energy of the reaction varied. The apparent activation energy of the reaction ranged from 23.36 to 89.13 kJ/mol at temperature ranging from 783 to 813 K, while it ranged from 14.30 to 68.34 kJ/mol at temperature ranging from 873 to 903 K.
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  Super-high bed sintering for iron ores: inhomogeneous phenomena and its mechanism during mineralizing

  Hui-bo Liu, Liang-ping Xu, Xi-duan Yang, Zhong-lin Dong, Qiang Zhong, Guang-hui Li

  钢铁研究学报(英文版). 2024, 31(8): 1850-1860.
  https://doi.org/10.1007/s42243-023-01117-x

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  The inhomogeneous sinter properties in super-high bed sintering have been reported in our previous research. To investigate the reasons for the inhomogeneous phenomena, detailed sampling and analysis of mixed material bed and sintered bed in super-high bed sintering plant were executed. The results indicated that the higher porosity and thinner dendrite of silico-ferrite of calcium and aluminum in the upper layer as well as dense structure and higher secondary hematite content in the lower layer led to the heterogeneities of mechanical strength and reduction properties exceeding 20% and 10%, respectively. From the bed top downward, the basicity of mixed material decreased from 2.13 to 1.68 because the average particle size increased from 2.65 to 4.56 mm. Fluxes and fuels gathered in finer particles (- 3 mm) of mixed material, and the - 3 mm particles of mixed material generated more liquid phase than +3 mm ones. The heat input of super-high sintering bed was inhomogeneous due to the heat accumulation effect and unreasonable fuel distribution. The inhomogeneous sintering heat condition in sintering bed resulted in the different quantities and properties of liquid phase. The inhomogeneous quantities and properties of liquid phase that were influenced by inhomogeneous distribution of chemical composition, particle size, and heat input led to inhomogeneous mineralizing results. Homogeneous mineralizing condition is the key for homogeneous super-high bed sintering.
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  Effective utilization of dolomitic lead–zinc waste rock by replacing dolomite as flux in iron ore sintering process

  Xin Wang, Cong-cong Yang, Jian Pan, De-qing Zhu, Zheng-qi Guo, Guang-hui Xia, Shi-juan Qu

  钢铁研究学报(英文版). 2024, 31(8): 1861-1872.
  https://doi.org/10.1007/s42243-023-01145-7

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  With increasingly stringent environmental protection policies, cost-effective and value-added treatment of massive lead–zinc waste rock (LZWR) generated from the preconcentration process has attracted substantial attention. A type of dolomitic LZWR with 18 wt.% MgO, 27 wt.% CaO, 0.29 wt.% Zn and 1.43 wt.% S was used as a replacement flux in the iron ore sintering process. Traditional sinter pot tests were carried out based on an industrial ore blend. The results show that replacing 0%–60% of dolomite with LZWR does not adversely affect the sintering productivity, fuel consumption rate, and the quality of the sinter products, while the Zn and S elements contained in LZWR can be effectively removed with the residual Zn and S contents of the resultant sinter products being less than 0.02 and 0.055 wt.%, respectively. However, substituting LZWR for dolomite as a flux inevitably increases the SO2 concentration in the sintering flue gas due to its high sulfur content. Considering the processing capacity of the sintering flue gas desulfurization system, the replacement ratio of dolomite can reach 40%, equal to LZWR consumption of 24.3 kg per ton of sinter. The SO₂ in sintering flue gas can be recovered to produce (NH4)₂SO₄ or H₂SO₄, while the volatilized Zn collected into the zinc-containing dust can be subsequently recycled by the rotary hearth furnace process. Therefore, it is technologically and economically feasible to use the LZWR as a replacement flux in the iron ore sintering process, providing a new way for the safe, large-scale and low-cost treatment of LZWR.
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  Effect of slag composition on kinetic behavior of deep deoxidation of 5 wt.% Si high-silicon austenitic stainless steel

  Guan-xiong Dou, Han-jie Guo, Jing Guo, Xue-cheng Peng, Qing-yun Chen

  钢铁研究学报(英文版). 2024, 31(8): 1873-1885.
  https://doi.org/10.1007/s42243-024-01250-1

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  Based on a thermodynamic study of 5 wt.% Si high-silicon austenitic stainless steel (SS-5Si) smelting using CaF₂–CaO– Al₂O₃–MgO–SiO₂ slag to obtain a low oxygen content of less than 10 ×10^-4 wt.%, a kinetic mass transfer model for deep deoxidation was established through laboratory studies, and the effects of slag components and temperature on deoxidation during the slag–steel reaction process of SS-5Si were systematically studied. The experimental data verified the accuracy of the model predictions. The results showed that the final oxygen content in the steel at 1873 K was mainly controlled by the oxygen content derived from the activity of SiO₂ regulated by the [Si]–[O] equilibrium reaction in the slag system; in particular, when the slag basicity R (R = w(CaO)/w(SiO₂), where w(CaO) and w(SiO₂) are the contents of CaO and SiO₂ in the slag, respectively) is 3, the Al₂O₃ content in the slag needs to be less than 2.7%. The mass transfer rate equation for the kinetics of the deoxidation reaction revealed that the mass transfer of oxygen in the liquid metal is the rate-controlling step under different slag conditions at 1873 K, and the oxygen transfer coefficient k_O,m increases with increasing the slag basicity from 4.0 × 10^-6 m s^-1 (R = 1) to 4.3 × 10^-5 m s^-1 (R = 3). kO,m values at R = 2 and R = 3 are almost the same, indicating that high slag basicity has little effect. The integral of the mass transfer rate equation for the deoxidation reaction of SS-5Si under different slag conditions is obtained. The total oxygen content of the molten steel decreases with increasing basicity from an initial content of 22 × 10^-4 to 3.2 × 10^-4 wt.% (R = 3), consistent with the change in k_O,m with slag basicity. At R = 2, the slag–steel reaction takes 15 min to reach equilibrium (w[O] = 5.5 × 10^-4 wt.%), whereas at R = 3, the slag–steel reaction takes 30 min to reach equilibrium (w[O] = 3.2 × 10^-4 wt.%). Considering the depth of deoxidation and reaction time of SS-5Si smelting, it is recommended the slag basicity be controlled at approximately 2. Similarly, the effect of temperature on the deep deoxidation of SS-5Si was studied.
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  Effect of Al content on modification behavior of non-metallic inclusions in high-strength steel treated with rare earth

  Zhan-peng Tie, Xue-yuan Jiang, Hai-yan Tang, Gen Li, Yu-hang Wang, Jia-quan Zhang

  钢铁研究学报(英文版). 2024, 31(8): 1886-1899.
  https://doi.org/10.1007/s42243-024-01177-7

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  The influence of Al content (0.0053, 0.0171, and 0.0578 wt.%) on the modification behavior of non-metallic inclusions in 20CrMoVTiB steel treated with rare earth elements was studied through high-temperature experiments and thermodynamic simulation. The results showed that the modification products varied with the Al content in steel under 0.01 wt.% of Ce addition. The formation sequence of typical rare earth inclusions in steel with the increase in Al content was Ce₂O₃ → CeAlO₃ → CeAl₁₁O₁₈, and the final stable products were highly Al content dependent. When the Al content was 0.0053 wt.%, the stable phase in steel was Ce₂O₃; while the [Al] reached 0.0171 wt.%, the stable phase became CeAlO₃. As the Al content reached 0.0578 wt.%, CeAl₁₁O₁₈ became the stable phase. As a result, increasing the Al content could inhibit the precipitation of Ce2O3 inclusions in steel while promote the formation of CeAlO₃ and CeAl₁₁O₁₈ inclusions. In addition, both Ca treatment and Ce treatment could effectively refine the size of inclusions in steel by changing their types. However, the feeding amount of Ca wire into molten steel should be appropriately reduced under the condition of adding Ce simultaneously, which is expected to be beneficial for an improved Ce treatment effect.
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  Effect of nano-carbon black content on wetting phenomenon of molten steel and alumina–carbon ceramic filter substrates

  Jin-wen Song, Wen Yan, Zhe Chen, Ying Liu, Shao-song Hong

  钢铁研究学报(英文版). 2024, 31(8): 1900-1913.
  https://doi.org/10.1007/s42243-024-01193-7

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  The effect of nano-carbon black content (0, 8 and 12 wt.%) on the wettability of molten steel on Al₂O₃–C substrates was investigated by the sessile drop wetting method at 1500 °C under argon atmosphere. At the beginning of the wetting experiment, the contact angle decreased with the increase in nano-carbon black content. As the wetting experiment progressed, FeAl₂O₄ layer and sheet Al₂O₃ layer were found at the interface between the molten steel and the Al₂O₃–C substrates with 0 and 8 wt.% nano-carbon black content, and the contact angle deceased with time. When the content of nano-carbon black was 12 wt.%, a large number of nano-Al₂O₃ whiskers were observed, which made the contact angle between the molten steel and Al₂O₃–C substrate become large. Based on the scanning electron microscope and energy dispersive spectrometry results, the formation mechanism of FeAl₂O₄ layer and Al₂O₃ layer and the interfacial reaction mechanism were proposed.
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  Selective sintering of magnesia–calcia materials by utilizing hot spots during induction sintering process

  Yun-jie Dong, Zhou-fu Wang, Hao Liu, Yan Ma, Xi-tang Wang, Nian Yi, Zhong-feng Xia, Yu-xuan Zhu, Cheng-ji Deng, Ling Zhang

  钢铁研究学报(英文版). 2024, 31(8): 1914-1922.
  https://doi.org/10.1007/s42243-023-01164-4

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  Magnesia–calcia refractories are widely used in the production process of clean steel due to their excellent high-temperature stability, slag resistance and ability to purify molten steel. However, there are still problems such as difficult sintering and easy hydration. Magnesia–calcia materials with various calcium oxide contents were prepared by using induction sintering, and the sintering property combined with the hydration resistance of the materials was investigated. The experimental results showed that the magnesia–calcia materials prepared under induction field had higher density, microhardness and hydration resistance. In particular, the relative density of induction sintered magnesia–calcia materials with 50 mol% CaO was greater than 98%, and the average grain size of CaO was 4.56 μm, which was much larger than that of traditional sintered materials. In order to clarify the densification and microstructure evolution mechanism of the magnesia–calcia materials, the changes in temperature and magnetic field throughout the sintering process were analyzed by using finite element simulation. The results showed that the larger heating rate and higher sintering temperature under the induction sintering mode were beneficial to the rapid densification. In addition, the hot spots generated within the material due to the difference in high-temperature electric conductivity between MgO and CaO were the critical factor to realize selective sintering in MgO–CaO system, which provides a novel pathway to solve the problem of difficult sintering and control the microstructure of high-temperature composite material used in the field of high-purity steel smelting.
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  Reoxidation of liquid steel and evolution of inclusions during protective atmosphere electroslag remelting of Ce-containing heat-resistant stainless steel

  Yu Zhao, Cheng-bin Shi, Shi-jun Wang, Peng Ren, Jing Li

  钢铁研究学报(英文版). 2024, 31(8): 1923-1935.
  https://doi.org/10.1007/s42243-023-01092-3

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  The evolution of Ce-containing inclusions and its correlation with the reoxidation of liquid steel during protective atmosphere electroslag remelting (ESR) of heat-resistant steel were studied. The reoxidation of liquid steel took place during the ESR, resulting in the oxygen pickup from 0.0014 to 0.0053 wt.%. The inclusions in the consumable electrode, liquid metal pool and remelted ingot are Ce₂O₂S and Ce₂O₃ inclusions invariably. The inclusions in the remelted ingot are originated from three ways: (I) the original inclusions from the electrode; (II) the newly formed Ce₂O₂S and Ce₂O₃ inclusions in the liquid metal pool by reoxidation remaining still in remelted ingot; (III) the newly generated Ce₂O₂S and Ce₂O₃ inclusions during cooling and solidification of liquid steel. The relative proportions of Ce₂O₃ inclusions in liquid metal pool and remelted ingot are 41% and 76.5%, respectively. The inclusions ranging from 2 to 5 μm in the remelted ingot take up 55%, followed by the inclusions smaller than 2 μm (43% of total inclusions). The number proportion of the Ce₂O₃ inclusions in the liquid metal pool which were removed by floating up into slag is 1.96 × 10^-5%.
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  Viscosity and structure of CaO–BaO–SiO2–Al2O3-based mold slags for continuous casting of high titanium steel with different TiO2 absorption

  Ya-tao Cui1, Xue-you Wang1, Xu-bin Zhang1, Qiang-qiang Wang1, Sheng-ping He1

  钢铁研究学报(英文版). 2024, 31(8): 1936-1946.
  https://doi.org/10.1007/s42243-024-01176-8

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  The effect of TiO₂ absorption into two different CaO–BaO–SiO₂–Al₂O₃-based mold slags from the steel plant on the viscosity, melting performance and microstructure of slags was investigated through the measurement of the viscosity– temperature relationship, melting temperature and Raman spectroscopy. The parameter of the number of non-bridging oxygen per tetrahedrally-coordinated atom (NBO/T) was also calculated to explain the microstructure variation of molten slags with different TiO₂ absorption. The variation of the actual slag consumption and the depth of the liquid slag in mold was explained through the comparison of the viscosity and the melting temperature of two different slags. The viscosity of mold slags (basicity = 0.6) decreased from 1.1 to 0.68 Pa s with the increase in the TiO₂ absorption from 0 to 10%, while that of slags (basicity = 0.7) decreased from 0.76 to 0.56 Pa s with the TiO₂ absorption from 0 to 6%. The activation energy of both two groups of slags had the tendency to decrease with the increasing TiO₂ absorption. The network structure of both two groups of slags measured by the Raman spectra showed that the fraction of complex structure units (Q1, Q2, Q3 and Al–O–Al) decreased and simple structure units (Al–O- and Q0) increased with the increase in TiO₂ absorption. NBO/T also increased with the increase in the TiO2 absorption, indicating that the absorption of TiO₂ into slags resulted in the destruction of silicate/aluminate structure. Hence, the absorption of TiO₂ into the current CaO–BaO–SiO₂–Al₂O₃ mold slags decreased the degree of polymerization of these slags and then led to the decrease of viscosity.
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  Mold breakout prediction based on computer vision and machine learning

  Yan-yu Wang, Qi-can Wang, Yong-chang Zhang, Yong-hui Cheng, Man Yao, Xu-dong Wang

  钢铁研究学报(英文版). 2024, 31(8): 1947-1959.
  https://doi.org/10.1007/s42243-024-01198-2

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  Breakout is the most serious production accident in continuous casting and must be detected and predicted by stable and reliable methods. The sticking region, which forms on the local copper plate and expanded into a ‘‘V’’ shape, is the typical precursor of breakout. Therefore, computer vision technology was exploited to visualize the temperature change rate of the copper plate based on the temperature signals from thermocouples; then, the static and dynamic features of the abnormal sticking region were extracted. Meanwhile, logistic regression and Adaboost models were used to study and identify these features, resulting in the development of a mold breakout prediction model based on computer vision and machine learning. The test results demonstrate that the proposed model can effectively distinguish anomalous temperature patterns and considerably reduce false alarms without any missing reports. As a result, the proposed method could offer valuable insights into the realm of abnormality detection and prediction during continuous casting process.
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  Aggregation of CeAlO₃ inclusions in heavy ingot of a steel containing 0.007% aluminum

  Qiu-yue Zhou, Jun-tao Ba, Lun Zhang, Wei Chen, Ying Ren, Li-feng Zhang

  钢铁研究学报(英文版). 2024, 31(8): 1960-1972.
  https://doi.org/10.1007/s42243-023-01154-6

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  The distribution of inclusions at the bottom of a Ce-treated heavy steel ingot was detected and calculated. The threedimensional morphology and spatial distribution of CeAlO₃ clusters were characterized using the electrolytic extraction and Micro-CT detection. A model of inclusion collision to predict the aggregation of CeAlO₃ inclusions in the ingot was established and validated by measured results. Inclusions were mainly CeAlO₃ and a small amount of Ce₂O₂S in the tundish after cerium treatment. The collision and aggregation of inclusions led to the formation of large clusters in the ingot during the solidification process. Large slag entrainment inclusions, large CeAlO₃ clusters and small CeAlO₃ particles were observed from the center to the edge of the ingot bottom. Large inclusions were mainly concentrated at the center. The number density of inclusions larger than 200 μm was 0.21 mm^-3. The maximum diameter of CeAlO₃ clusters was 1340 μm. From the edge to the radial center and from the bottom to the top, the average diameter of inclusions gradually increased due to the longer solidification time of the ingot.
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  Role of texture before rolling: a research based on texture and magnetic properties of 4.5 wt.% Si non-oriented electrical steel

  Yu-fan Wang, Guo-qing Zu, Shi-cheng Sun, Ying Han, Wei-wei Zhu, Hui Wu, Yu Zhao, Xu Ran

  钢铁研究学报(英文版). 2024, 31(8): 1973-1986.
  https://doi.org/10.1007/s42243-024-01187-5

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  The evolution of microstructure, texture, and magnetic properties with random texture, near-copper texture, weak nearcube texture, and strong k fiber (\001[//ND (normal direction)) before rolling of non-oriented electrical steel was studied. Three recrystallized hot bands with different textures but similar grain sizes were prepared by pre-annealing at lowtemperature and high-temperature normalization annealing. It was observed that the final annealed products exhibited similar recrystallized microstructures. By contrast, the final annealed product with more k fiber before rolling exhibited a stronger cube texture. With the k fiber before rolling becoming stronger, the proportion of {111}\110[deformed matrices became larger, which could be observed in the early recrystallization stage. The overwhelmingly dominant k orientation nuclei are formed in the {111}\110[deformed matrix and become the dominant texture. Eventually, the best magnetic properties are obtained in the products with strong k fiber before rolling, corresponding to the strong cube texture and low anisotropy parameter.
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  Mechanical properties and microstructure of Mg-treated and Catreated industrial H13 steel after quenching and tempering

  Jun-ying Yue, Dong Hou, De-yong Wang, Tian-peng Qu, Xiang-long Li, Jun Tian

  钢铁研究学报(英文版). 2024, 31(8): 1987-2001.
  https://doi.org/10.1007/s42243-024-01185-7

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  The effect of magnesium treatment and calcium treatment on the microstructure and mechanical properties of industrial H13 steel after quenching and tempering was investigated. The impact toughness and tensile tests were mainly carried out, and the microstructure was observed by scanning electron microscopy, electron backscattered diffraction, and X-ray diffraction. The results show that magnesium treatment is still feasible in industrial trials. It is mainly manifested in the refinement of lath martensite and carbides. Compared with calcium treatment, the prior austenite grains and carbides size of industrial H13 steel treated with magnesium decreased by 3.17 μm after quenching. After quenching and tempering, the carbides (especially V-rich carbides) in Mg treatment obviously spheroidized and distributed uniformly and increased in quantity significantly. The lath martensite size is reduced from 2.45 to 2.31 μm. This suggests that magnesium treatment was able to yield smaller grains and more evenly distributed carbides. Moreover, the impact toughness, yield strength, and ultimate tensile strength of industrial H13 steel with magnesium treatment increased by 28%, 65.5 MPa and 123.7 MPa, respectively. The increment of strength mainly comes from dislocation strengthening, grain refinement strengthening, and precipitation strengthening, among which precipitation strengthening accounts for the largest proportion.
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  Machine learning for prediction of retained austenite fraction and optimization of processing in quenched and partitioned steels

  Shuai Wang, Jie Li, Li-yang Zeng, Xun-wei Zuo, Nai-lu Chen, Yong-hua Rong

  钢铁研究学报(英文版). 2024, 31(8): 2002-2013.
  https://doi.org/10.1007/s42243-023-01114-0

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  The metastable retained austenite (RA) plays a significant role in the excellent mechanical performance of quenching and partitioning (Q&P) steels, while the volume fraction of RA (V_RA) is challengeable to directly predict due to the complicated relationships between the chemical composition and process (like quenching temperature (QT)). A Gaussian process regression model in machine learning was developed to predict V_RA, and the model accuracy was further improved by introducing a metallurgical parameter of martensite fraction ðfa0 Þ to accurately predict V_RA in Q&P steels. The developed machine learning model combined with Bayesian global optimization can serve as another selection strategy for the quenching temperature, and this strategy is very efficient as it found the ‘‘optimum’’ QT with the maximum V_RA using only seven consecutive iterations. The benchmark experiment also reveals that the developed machine learning model predicts V_RA more accurately than the popular constrained carbon equilibrium thermodynamic model, even better than a thermokinetic quenching–partitioning–tempering–local equilibrium model.
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  High-temperature stability of retained austenite and plastic deformation mechanism of ultra-fine bainitic steel isothermally treated below Ms

  Ting-ting He, Feng Hu, Kun Wang, Wen Zhou, Li Li, Serhii Yershov, Kai-ming Wu

  钢铁研究学报(英文版). 2024, 31(8): 2014-2030.
  https://doi.org/10.1007/s42243-023-01151-9

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  The mechanical properties of the sample and the stability of retained austenite were studied by designing two kinds of ultra-fine bainitic steel with different heat treatment methods (austempering above and below Ms (martensite start temperature)), which were subjected to tensile tests at 20 and 450 °C, respectively. The results show that compared to room temperature (20 °C) tensile properties, the uniform elongation of the sample at high temperature (450 °C) significantly decreased. Specifically, the uniform elongation of the sample austempered above Ms decreased from 8.0% to 3.5%, and the sample austempered below Ms decreased from 10.9% to 3.1%. Additionally, the tensile strength of the sample austempered above Ms significantly decreased (from 1281 to 912 MPa), and the sample austempered below Ms slightly decreased (from 1010 to 974 MPa). This was due to the high carbon content (1.60 wt.%), high mechanical stability, low thermal stability for the retained austenite of the sample austempered below Ms. Besides, the retained austenite decomposed at high temperatures, the carbon content and transformation driving force were significantly reduced, the transformation rate increased, and the phase transformation content reduced.
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  An experimental study on effects of temperature gradient on microstructure of a 308L stainless steel manufactured by directed energy deposition

  Ting Dai, De-yu Gu, Yu-wen Qiu, Wei Guo, Hui Ding, Yi-wei Sun

  钢铁研究学报(英文版). 2024, 31(8): 2031-2040.
  https://doi.org/10.1007/s42243-023-01158-2

  摘要 ( )   可视化   收藏

  The effect of spatial temperature gradient on the microstructural evolution of a 308L stainless steel during the directed energy deposition (DED) process was experimentally investigated. A novel cooling system was designed and incorporated to a DED system in order to control the temperature gradient along the deposition direction during solidification. During deposition, the workpiece was placed on a lifting platform, and as the deposition process proceeded, the platform and workpiece were gradually lowered into cooling water so that the temperature gradient along the deposition direction could be controlled and maintained stable during the deposition process. The microstructure characterization results indicated that a deposition strategy with higher G and G/R values (where G is temperature gradient and R is solidification rate) produced finer cellular grains that were better aligned with the deposition direction, while a deposition strategy with lower G and G/R values produced columnar grains with larger primary arm spacing and less aligned with the deposition direction.
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  Changes in microstructure and properties of weld heat-affected zone of high-strength low-alloy steel

  Shu-jun Jia, Qi-lin Ma, Yu Hou, Ba Li, He-song Zhang, Qing-you Liu

  钢铁研究学报(英文版). 2024, 31(8): 2041-2052.
  https://doi.org/10.1007/s42243-023-01133-x

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  The evolution of the microstructure and toughness of APL5L X80 pipeline steel after thermal welding simulation was investigated by X-ray diffraction, electron backscatter diffraction, and transmission electron microscopy. The results indicated that primary heat-affected zones can be divided into weld, coarse-grained, fine-grained, intercritical, and subcritical zones. The microstructure of the weld zone is mainly composed of bainitic ferrite and a small amount of granular bainite; however, the original austenite grains are distributed in the columnar grains. The structure of the coarse-grained zone is similar to that of the weld zone, but the original austenite grains are equiaxed. In contrast, the microstructure in the fine-grained zone is dominated by fine granular bainite, and the effective grain size is only 8.15 μm, thus providing the highest toughness in the entire heat-affected zone. The intercritical and subcritical zones were brittle valley regions, and the microstructure was dominated by granular bainite. However, the martensite–austenite (M/A) constituents are present in island chains along the grain boundaries, and the coarse size of the M/A constituents seriously reduces the toughness. The results of the crack propagation analyzes revealed that high-angle grain boundaries can significantly slow down crack growth and change the crack direction, thereby increasing the material toughness. The impact toughness of the low-temperature tempering zone was equivalent to that of the columnar grain zone, and the impact toughness was between those of the critical and fine-grained zones.
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  Online estimation and characteristic analysis of double nugget diameters during aluminum/steel resistance spot welding process

  Kang Zhou, Wen-xiao Yu, Bao-kai Ren, Gang Wang

  钢铁研究学报(英文版). 2024, 31(8): 2053-2067.
  https://doi.org/10.1007/s42243-023-01167-1

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  Online estimation of the double nugget diameters was performed by means of a back propagation neural network. The double nugget diameters were obtained using actual welding experiment and numerical simulation, according to different characteristics of aluminum nugget and steel nugget. The input of the neural network was some key characteristic parameters extracted from dynamic power signal, which were peak point, knee point and their variation rate over time, as well as heat energy delivered into the welding system. The architecture of the neural network was confirmed by confirming the number of neurons in hidden layer through a series of calculations. The key parameters of the neural network were obtained by means of training 81 arrays of data set. Then, the neural network was used to test the remaining 20 arrays of verifying data set, and the results showed that both of the mean errors for the two nugget diameters were below 3%. In addition, corresponding analyses showed that the accuracy of two nugget diameters was higher than that of tensile-shear strength.
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  Nanoindentation responses of NiCoFe medium-entropy alloys from cryogenic to elevated temperatures

  Qin-qin Xu, Kamran Karimi, Amirhossein H. Naghdi, Wen-yi Huo, Chong Wei, Stefanos Papanikolaou

  钢铁研究学报(英文版). 2024, 31(8): 2068-2077.
  https://doi.org/10.1007/s42243-024-01194-6

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  NiCoFe alloy, a medium-entropy alloy, shows potential for applications in extreme environments. However, there is a theoretical barrier concerning the unclear understanding of its high-temperature dislocation motion mechanism. The load response exhibits distinct signatures relevant to thermal activation, most notably a decrease in critical force (i.e., softening) from cryogenic to elevated temperatures, e.g., from 200 to 1000 K. The onset of plasticity is characterized by the nucleation of stacking faults and prismatic loops at low temperatures, whereas the surface nucleation of Shockley partial dislocations dominates plasticity at elevated temperatures. We show that thermal effects lead to non-uniform atom pile-ups and control the rate of phase transformation with increasing indentation depth. The findings in this work extend the understanding of the mechanical response of NiCoFe alloys under indentation at different temperatures, shedding light on the underlying dislocation motion mechanisms and surface deformation characteristics. The observed transformationinduced plasticity mechanism has implications for the properties of medium-entropy alloys and their potential applications in extreme environments.