2024年, 第31卷, 第11期　刊出日期：2024-11-25

  

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  Development of accumulative roll bonding for metallic composite material preparation and mechanical/functional applications

  Bo Feng, Hao-kun Yang, Xiao-hui Li, Xiao-wei Feng, Tian-lai Chen, Guo-feng Li

  钢铁研究学报（英文版）. 2024, 31(11): 2611-2621.
  https://doi.org/10.1007/s42243-024-01244-z

  摘要 ( ) PDF全文 ( )   可视化   收藏

  Accumulative roll bonding (ARB) is a severe plastic deformation method to prepare the metallic composite material by physical method at room to elevate temperature, without the generation of additional waste solid or gas. With the physical characteristicsmulti-material and hybrid structure, the mechanical and function properties of the ARB composite material, like Al/steel, Al/Mg, Al/Cu, etc., shall have the “1+1>2” effect on the mechanical and functional properties, including the remarkable properties that include lightweight, high strength, thermal/electrical conductivity, electromagnetic shielding, and other functions. To deeply investigate the preparation method and microstructural evolution of various metal laminates by ARB, as well as the mechanical and functional properties of the laminate, an overview of the history of ARB technique, the breakthrough of ARB sheet properties, as well as the relative products in industries is provided. Additionally, the future development of ARB technology and the utilization of composite materials in different areas will be discussed.
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  A novel approach to enhance decrepitation temperature and reducibility of ultrafine iron ore concentrate pellets

  B.L. Wen, Z.H. Fan, J.X. Li, D.L. Liu, J.L. Yang

  钢铁研究学报（英文版）. 2024, 31(11): 2622-2632.
  https://doi.org/10.1007/s42243-024-01268-5

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  Utilizing ultrafine iron ore concentrate for pellet production can expand domestic iron ore resources in China and promote the utilization of low-grade ores. However, a challenge arises with the low decrepitation temperature and reducibility in the preparation process of ultrafine iron ore concentrate pellets. To address the challenge, a novel approach was proposed, which incorporated straw powder as an additive to enhance pellet porosity, thereby improving the decrepitation temperature and reducibility of ultrafine iron ore concentrate pellets. The effect of varying proportions of straw powder (0.0-2.0%) on the characteristics of ultrafine iron ore concentrate pellets was examined. Results indicate that at a 2.0% straw powder ratio, pellet decrepitation temperature notably rises from 380 to 540 °C, while the reducibility index escalates from 25.7% to 48.1%. Nevertheless, the addition of straw powder results in diminished drop strength, compressive strength of green pellets, and cold crushing strength of fired pellets. In addition, enhanced pellet reducibility leads to exacerbated reduction swelling index and reduction degradation index. Despite these effects, all parameters remain within an acceptable range.
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  Distinct element method simulation of mechanical properties of material layer of pellet belt roasting machine

  Yin-hua Tang, Xing-wang Li, Xu Gao, Tao Yang, Hong-ming Long, Jie Lei

  钢铁研究学报（英文版）. 2024, 31(11): 2633-2644.
  https://doi.org/10.1007/s42243-024-01214-5

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  The thick layer and graded feeding technology of a belt roasting machine is an effective method for improving the production efficiency and quality index of pellet production, and a reasonable design of the mechanical structure of the layer is the basis for optimizing the heat andmass transfer performance of the layer. Janssen effect and von Mises yield criterion were used to establish a simplified mathematical model describing the elastic and plastic deformation of the green pellet under the action of an external force. The mechanical characteristics of extrusion, contact, and elastic-plastic deformation between green pellet particles in the material layer of the belt roastingmachine weremodeled usingEDEMsoftware.For a green pellet size of 12mm,as the layer height increases from 300 to 1000 mm, the maximum vertical pressure on the pellets increases from 11.64 to 24.01 N, and the porosity decreases from 27.04% to 22.01%. As the layer height increases, the contact between the green pellets becomes more intense, and the force chain structure of the layer becomes more stable; the Janssen effect is observed when the layer reaches 700 mm. The compressive strength of the green pellets is linearly related to the particle size, and the compressive strength increases with an increase in particle size.At a layer height of 600 mm, as the particle size of the green pellets increases from 8 to 20 mm, themaximum vertical pressure increases from 7.54 to 44.16 N, and the porosity increases from23.20% to 31.47%,while the yield per unit of the layer decreased by 12.1%. Small particles have a more stable force chain structure, larger comparative area, and higher production efficiency; however, their compressive strength is lower. Large particles have higher compressive strength and good permeability in the layer, but the production efficiency is relatively low. In actual production, a variety of factors should be integrated to optimize the feeding, and a multi-granularity graded feeding is the most ideal feeding.
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  Production of ultrafine iron powder by low-temperature hydrogen reduction: properties change with temperature

  Min Gan, En-di Guo, Hao-rui Li, Yun-can Cao, Xiao-hui Fan, Zhi-yun Ji, Zeng-qing Sun

  钢铁研究学报（英文版）. 2024, 31(11): 2645-2654.
  https://doi.org/10.1007/s42243-024-01228-z

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  Ultrafine iron powder is widely used due to its excellent performance. Hydrogen reduction of fine-grained high-purity iron concentrate to prepare ultrafine iron powder has the advantages of low energy consumption, pollution-free, and low cost. The hydrogen reduction of high-purity iron concentrates, characterized by the maximum particle size of 6.43 lm when the cumulative distribution is 50% and the maximum particle size of 11.85 lm when the cumulative distribution is 90% while the total iron content of 72.10%, was performed. The hydrogen reduction could be completed at 425 °C, and the purity of ultrafine iron powders was more than 99 wt.% in the range of 425-650 °C. Subsequently, the effect of reduction temperature on various properties of ultrafine iron powder was investigated, including particle morphology, particle size, specific surface area, lattice parameters, bulk density, and reaction activity. It was found that the reaction activity of the iron powders prepared by hydrogen reduction was much higher than that of the products of carbonyl and liquid phase synthesis. Below 500 °C, the reduced iron powders were nearly unbound, with a small particle size and a low bulk density. The particles had a porous surface, with a specific surface area as high as 11.31 m² g^-1. The crystallization of reduced iron powders was imperfect at this time, the amorphization degree was prominent, and the interior contained a high mechanical storage energy, which had shown high reaction reactivity. It was suitable for catalysts, metal fuels, and other functionalized applications.
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  Emission characteristics and control technology of heavy metals during collaborative treatment of municipal solid waste incineration fly ash in iron ore sintering process

  Xiao-hui Fan, Zhi-an Zhou, Bin-bin Huang, Zhi-yun Ji, Min Gan, Zeng-qing Sun, Xu-ling Chen, Xiao-xian Huang, Guo-jing Wang

  钢铁研究学报（英文版）. 2024, 31(11): 2655-2663.
  https://doi.org/10.1007/s42243-024-01269-4

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  The municipal solid waste incineration fly ash (MSWI-FA) contains a large amount of heavy metals, and the process of iron ore sintering and treating fly ash needs to pay attention to the migration characteristics of heavy metals. The impact of the application of MSWI-FA in the sintering process on the emission law of heavy metals in the collaborative treatment process was studied, and corresponding control technologies were proposed. The results showed that the direct addition of water washing fly ash (WM-FA) powder resulted in varying degrees of increase in heavy metal elements in the sinter. As the amount of WM-FA added increases, the content of heavy metal elements correspondingly increases, and an appropriate amount of WM-FA added is 0.5%-1.0%. The migration mechanism of heavy metals during the sintering treatment of WMFA was clarified. Heavy metals are mainly removed through direct and indirect chlorination reactions, and Cu and Cr can react with SiO₂ and Fe₂O₃ in the sintered material to solidify in the sinter. Corresponding control techniques have been proposed to reduce the heavy metal elements in WM-FA through the pre-treatment of WM-FA. When the WM-FA was fed in the middle and lower layers of the sintered material, the high temperature of the lower layer was utilized to promote the removal of heavy metals. The Ni element content has decreased from 130 to 90 mg kg^-1, and the Cd removal rate has increased by 23%. The removal rates of Cd and Cr elements increase by 2.4 and 5.5 times, respectively. There is no significant change in sintering indexes.
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  Reaction intermediates and products characterisation of NH₃ in desulphurisation with activated coke

  Wei-li Zhang, Meng Wang, Wen-zhe Si, Jun-hua Li

  钢铁研究学报（英文版）. 2024, 31(11): 2664-2674.
  https://doi.org/10.1007/s42243-024-01241-2

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  The sulphate is an important factor restricting the efficient and stable operation of the activated coke (AC) flue gas purification system. The simulation experiments and in situ infrared tests of AC taken from desorption tower of the AC flue gas purification system were carried out to first calibrate the thermal desorption characteristics of adsorbed NH₃ and sulphate and explore the reaction behaviour of NH₃ with SO₂ and H₂SO₄. On this basis, some advice for optimising the sulphate generation was put forward to improve the purification efficiency of the AC system. The results show that the temperatures of the desorption of adsorbed NH₃, the decomposition of (NH₄)₂SO₄ and NH₄HSO₄ are 224, 276 and 319 °C, respectively, which lays the foundation for the quantitative analysis of sulphate on AC. Regardless of the NH₃ amount, only a small portion of H₂SO₄ is converted to sulphate, as the H₂SO₄ deposited in AC pores or agglomerated together could not come into contact with NH₃. The final reaction product of NH₃ and SO₂ is mainly (NH₄)₂SO₄ which is continuously generated because the newly generated H₂SO₄ is continually exposed to NH₃, if NH₃ is enough. The reaction of NH₃ with H₂SO₄ takes precedence over with NH₄HSO₄. In the initial stages in which H₂SO₄ is exposed to NH₃, the product is essentially all NH₄HSO₄ as intermediate. Then, it is further converted to (NH₄)₂SO₄ whose amount reaches equilibrium when the accessible H₂SO₄ is exhausted. All the NH₃ adsorbed on AC entering the desulphurisation tower generates NH₄HSO₄, but the amount is limited. The remaining SO₂ entering the denitrification tower mainly generates (NH₄)₂SO₄; thus, limiting the remaining SO₂ amount is necessary to guarantee denitrification efficiency. When the NH₃ injection is changed to the desulphurisation tower, the initial NH₃ injection rate can be increased to complete the conversion of accessible H₂SO₄ as soon as possible in order to obtain higher denitrification efficiency.
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  Effect of TiO₂ and BaO on viscosity and potassium removal capacity of blast furnace slag

  Jian-tao Ju, Xin-yi Li, Liu-le Wei, Xiang-dong Xing

  钢铁研究学报（英文版）. 2024, 31(11): 2675-2683.
  https://doi.org/10.1007/s42243-024-01222-5

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  In order to increase the utilization rate of vanadium-titanium magnetite in blast furnace smelting, the viscosity and potassium removal capacity of CaO-SiO₂-Al₂O₃-MgO-BaO-TiO₂ slag (CaO/SiO₂ = 1.05, 1-5 wt.% BaO, 2-20 wt.% TiO₂) were studied for slag optimization using the cylinder method and slag-metal equilibrium technique, respectively. Also, the structural properties of the slag were characterized by Fourier transform infrared spectroscopy. The concept of “a ring structure of Ti-O-Si” was proposed to express the change in the viscosity of the blast furnace slag. The results showed that the viscosity of slag increased with the increase in BaO content while the potassium removal capacity decreased. Furthermore, an increase in TiO₂ content from 2 to 20 wt.% resulted in a decrease in viscosity and an increase in potassium removal capacity. The Fourier transform infrared spectroscopy results showed that the charge compensation of Ba²⁺ can form complex aluminosilicate structure and increase the viscosity of slag. Meanwhile, with the increase in TiO₂ content, Ti⁴⁺ ions replace Si⁴⁺ in the silicon-oxygen tetrahedral structure, thereby reducing the degree of polymerization of the silicate network and decreasing the viscosity.
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  Comparison study on hot state modification of converter slag by adding Al₂O₃ or SiO₂

  Yu-feng Tian, Guang-qiang Li, Yong-qian Li, Yu Liu

  钢铁研究学报（英文版）. 2024, 31(11): 2684-2692.
  https://doi.org/10.1007/s42243-023-01172-4

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  The value-added utilization of converter steel slag is crucial, with China’s annual production having reached 100 million tons. The utilization of converter slag in the construction materials sector is limited as it undergoes volume expansion during the aging process, mainly caused by the hydration reaction of free calcium oxide present in the slag. The influence of alumina addition on the mineral transformation of typical industrial converter slag was investigated. Different quantities of alumina were introduced into the slag, and the original and modified slags were remelted under argon atmosphere, followed by quenching. The experimental results were compared with thermodynamic simulation calculations for further analysis. As the alumina content increases, it reacts with the free calcium oxide in slag, leading to the formation of lowmelting- point calcium aluminoferrite. Additionally, alumina addition effectively reduces slag viscosity. Finally, an assessment of the energy consumption for alumina-modified and silica-modified converter slags was presented.
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  Nunder coupling effects of annular gas curtain and swirling flow at tundish upper nozzle

  Xu-feng Qin, Chang-gui Cheng, Yang Li, Wei-li Wu, Hao Chen, Chao-fa Zhao, Yan Jin

  钢铁研究学报（英文版）. 2024, 31(11): 2693-2709.
  https://doi.org/10.1007/s42243-024-01212-7

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  A three-dimensional mathematical model has been established for a novel metallurgy process coupling an annular gas curtain with swirling flow at tundish upper nozzle. The discrete phase model and volume of fluid model were applied to simulate the gas-liquid multiphase flow behavior in tundish and nozzle. The effect of argon flow rate on the migration behavior of bubbles and interface behavior between steel and slag was also investigated. The presented results indicate that the novel coupling process can significantly change the flow pattern in the stream zone of a tundish, prolong the average residence time of liquid steel, and reduce the dead fraction. A complete annular gas curtain is formed around the stopper rod of tundish. Under the action of drag force of liquid steel, a part of small bubbles enter the nozzle through the swirling grooves and gather toward the center of the nozzle by centripetal force. As the argon flow rate increases, the volume fraction of argon gas entering the nozzle increases, which enhances the swirl intensity and increases the concentration of bubbles in the nozzle. To avoid the formation of slag open eye in tundish, the argon flow rate should not exceed 8 L min^-1.
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  New electromagnetic variable flow device for slab continuous casting mold: mechanical design and magnetic field analysis

  Xi-qing Chen, Pu Wang, Shun Liu, Hong Xiao, Lin-lin Lei, Jia-quan Zhang

  钢铁研究学报（英文版）. 2024, 31(11): 2710-2726.
  https://doi.org/10.1007/s42243-024-01255-w

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  Obtaining a reasonable mold flow field for casting slabs with different sections is challenging by solely modifying the nozzle structure and continuous casting process. Research was conducted on small-sectioned (1000 mm 9 220 mm) and large-sectioned (3250 mm 9 220 mm) slab continuous casting molds with a fixed nozzle form (concave bottom nozzle, side port inclination angle of 0°). A three-dimensional electromagnetic model is established to analyze the current frequency, installation position, and rotation angle under the active deceleration mode and acceleration mode. The results indicate that, regardless of the deceleration mode for small-sectioned slabs or the acceleration mode for large-sectioned slabs, the magnetic flux density in the mold decreases with increasing current frequency. However, the maximum electromagnetic force initially increases and then decreases, suggesting that both electromagnetic modes have the same optimal current frequency (3 Hz). The optimal mechanical design parameters for the deceleration mode of electromagnetic variable flow device (EM-VFD) with the small-sectioned slab are as follows: installation position Z = 115 mm and rotation angle of 15°, ensuring that the maximum electromagnetic force is applied to the nozzle jet area. For the acceleration mode of the large-sectioned slab EM-VFD, the optimal mechanical design parameters are as follows: Z = 115 mm and rotation angle of 10°, ensuring that the maximum electromagnetic force is applied to 1/4 and 3/4 areas of the wide face. These findings indicate that the new electromagnetic variable flow device, which can actively adjust the flow rate and angle of the steel even under given working conditions, provides the possibility for reasonable control of the mold’s flow field.
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  Assessment of internal quality of billets using ultrasonic three-dimensional layered characterization

  Yan-bo Liu, Min Li, Zheng Zhao, Zhong-xin Wang, De-bin Yang

  钢铁研究学报（英文版）. 2024, 31(11): 2727-2739.
  https://doi.org/10.1007/s42243-024-01292-5

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  To address the challenge of visualizing internal defects within castings, ultrasonic nondestructive testing technology has been introduced for the detection and characterization of internal defects in castings. Ultrasonic testing is widely utilized for detecting and characterizing internal defects in materials, thanks to its strong penetration ability, wide testing area, and fast scanning speed. However, traditional ultrasonic testing primarily relies on one-dimensional waveforms or twodimensional images to analyze internal defects in billets, which hinders intuitive characterization of defect quantity, size, spatial distribution, and other relevant information. Consequently, a three-dimensional (3D) layered characterization method of billets internal quality based on scanning acoustic microscope (SAM) is proposed. The method starts with a layered focus scanning of the billet using SAM and pre-processing the obtained sequence of ultrasonic images. Next, the ray casting is employed to reconstruct 3D shape of defects in billets, allowing for characterization of their quality by obtaining characteristic information on defect spatial distributions, quantity, and sizes. To validate the effectiveness of the proposed method, specimens of 42CrMo billets are prepared using five different processes, and the method is employed to evaluate their internal quality. Finally, a comparison between the ultrasonic image and the metallographic image reveals a difference in dimensional accuracy of only 2.94%. The results indicate that the new method enables visualization of internal defect information in billets, serving as a valuable complement to the traditional method of characterizing their internal quality.
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  Dynamic modeling and analysis on rigid-flexible coupling between vertical chatter and transverse bending vibration in process of cold rolling

  Xiao-yong Wang, Zhi-ying Gao, Yan-li Xin, Qing-dong Zhang

  钢铁研究学报（英文版）. 2024, 31(11): 2740-2754.
  https://doi.org/10.1007/s42243-024-01183-9

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  Considering the dynamic variation of roll gap and the transverse distribution of dynamic rolling force along the work roll width direction, the movement and deformation of rolls system, influenced by the coupling of vertical chatter and transverse bending vibration, may cause instability and also bring product defect of thickness difference. Therefore, a rigidflexible coupling vibration model of the rolls system was presented. The influence of dynamic characteristics on the rolling process stability and strip thickness distribution was investigated. Firstly, assuming the symmetry of upper and lower structures of six-high rolling mill, a transverse bending vibration model of three-beam system under simply supported boundary conditions was established, and a semi-analytical solution method was proposed to deal with this model. Then, considering both variation and change rate of the roll gap, a roll vertical chatter model with structure and process coupled was constructed, and the critical rolling speed for self-excited instability was determined by Routh stability criterion. Furthermore, a rigid-flexible coupling vibration model of the rolls system was built by connecting the vertical chatter model and transverse bending vibration model through the distribution of dynamic rolling force, and the dynamic characteristics of rolls system were analyzed. Finally, the strip exit thickness distributions under the stable and unstable rolling process were compared, and the product shape and thickness distribution characteristics were quantitatively evaluated by the crown and maximum longitudinal thickness difference.
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  Effects of Mg-Ca treatment and Ca treatment on impact toughness and morphology of sulfides in 45MnVS non-quenched and tempered steel

  Tian-yin Zhan, Jun Tian, Xiang-long Li, Li-juan Su, Dong Hou, Tian-peng Qu, De-yong Wang

  钢铁研究学报（英文版）. 2024, 31(11): 2755-2773.
  https://doi.org/10.1007/s42243-024-01215-4

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  An industrial experiment was conducted at a certain steel plant in China to compare and analyze the effects of Ca treatment and Mg-Ca treatment on inclusions in 45MnVS non-quenched and tempered steel. Through scanning electron microscopyenergy dispersive scanning analysis of the morphology and composition of inclusions, as well as Aspex quantitative analysis of their quantity, type and size, the formation mechanism of MnS-oxide (MnS inclusions with oxide cores) was intensively studied. The influence of sulfide morphology on the impact properties of steel was also analyzed. The results show that the quantity percentage of spindle-shaped sulfides in Ca-treated steel is 19.99%, and that in Mg-Ca-treated steel is 35.38%. Compared with Ca-treated steel, there are more MnS-oxide inclusions in Mg-Ca-treated steel. Controlling the content of Ca and Mg in the oxide core of MnS-oxide inclusion above 10 wt.% and the area ratio below 5 would contribute to the formation of spindle-shaped inclusions after rolling. The mismatch between MnS and oxides decreases with the increase in MgO content in the oxides, which is beneficial to nucleation and precipitation of MnS with this type of oxides as the core. Under the same deformation conditions, the size of sulfide does not affect its aspect ratio. Under the experimental conditions, the inclusion containing a certain amount of MgO can enhance its sulfur capacity, facilitating the formation of composite sulfides. The transverse impact energy of Ca-treated steel is 25.785 J, and that of Mg-Ca-treated steel is 32.119 J. Compared with the traditional Ca-treatment, Mg-Ca treatment can increase the number of spindle-shaped sulfides in the steel, thereby improving the transverse impact toughness of the steel and reducing the anisotropy of the mechanical properties of the material.
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  Effect of MgO on structure and crystallization behavior of CaO-SiO₂-Al₂O₃ inclusions in Si-Mn deoxidized steel

  Qi Xu, Yao-qing Meng, Jian-li Li

  钢铁研究学报（英文版）. 2024, 31(11): 2774-2787.
  https://doi.org/10.1007/s42243-024-01236-z

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  To avoid coarse crystallization of glassy inclusions in Si-Mn deoxidized steel during hot rolling, the effect of MgO on the structure and crystallization behavior of CaO-SiO₂-Al₂O₃ inclusions was investigated. The results showed that the crystallization temperature of the oxide melts decreased with increasing MgO content from 0 to 15.7 wt.%, which suggested that the addition of MgO would increase the temperature range of the crystalline transition. The increase in MgO content could decrease the crystallization activation energy of inclusions. With the increase in MgO content, the relative fractions of Q⁰_Si and Q¹_Si structure units increased, and those of structure units Q₂^Si, Q₃^Si, and Q₄^Si decreased, increasing the depolymerization degree of the silicate structure. The crystallization ratio of glassy inclusions in the steel crucible increased from 19.7% to 98.3% with increasing MgO content from 0 to 15.7 wt.%. The addition of MgO improved the crystallization ability of inclusions, because MgO provides free oxygen O^2- to destroy the bridging oxygens and form nonbridging oxygens O^-, which depolymerizes silicate network structure and simplifies the [SiO₄]-tetrahedral structure. In addition, MgO would promote the precipitation of the Mg-containing phases with a high melting point. When the MgO content was increased above 12.1 wt.%, MgO·Al₂O₃ and 2MgO·SiO₂ crystalline phases would precipitate from the inclusions.
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  Estimation of probable maximum aspect ratio of MnS inclusions in non-quenched and tempered steel after isothermal compression

  Jun-yu Liu, Cheng-song Liu, Yong Wang, Hua Zhang, Rui-juan Bai, Wei Wang, Qing-bo Wang, Hong-wei Ni

  钢铁研究学报（英文版）. 2024, 31(11): 2788-2801.
  https://doi.org/10.1007/s42243-024-01200-x

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  To clarify the deformation behavior of MnS inclusions in a non-quenched and tempered steel at three different positions (edge, 1/2 radius and center) in the cross-section of the billet in the course of hot rolling, isothermal compression experiments were performed under the deformation temperature range from 1073 to 1473 K, the reduction rates from 25% to 75% and the strain rates from 0.01 to 10 s^-1. The variations of deformability features (i.e., aspect ratios, size distributions, and morphologies) of MnS inclusions with those isothermal compression parameters were revealed. The evaluation of the probable maximum aspect ratio of MnS inclusions at the three different positions in the cross-section of the billet after hot rolling was examined using the statistical analysis of extreme values. Results showed that the number densities of MnS inclusions at three different positions (edge, 1/2 radius and center) in the cross-section of the steel billet only fluctuated slightly when the deformation parameters varied in the isothermal compression, while the average inclusion aspect ratios in all cases generally have a negative correlation with the deformation temperature and positive correlations with the reduction ratio and the strain rate. Statistical analysis reveals that larger inclusions deform more easily during hot rolling. The effect of rolling temperature on the extreme value of the aspect ratio of inclusions is the smallest, while the effects of initial size, reduction ratio and strain rate are more significant.
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  Effect of Mg-treatment on transformation of oxide inclusions in X80 pipeline steel

  Ping Shen, Hao Zhang, Kang Xu, Shuai Liu, Jin-xing Jiang, Jian-xun Fu

  钢铁研究学报（英文版）. 2024, 31(11): 2802-2814.
  https://doi.org/10.1007/s42243-024-01208-3

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  In order to investigate the modification behavior and regularity of inclusions in X80 pipeline steel by Mg-treatment, the comparative industrial experiments of Mg-treatment and Ca-treatment in X80 pipeline steel were carried out. Mg and Ca were added to the steel in the form of cored wire after RH (Ruhrstahl-Hereaeus vacuum degassing) process. After adding Ca-containing cored wire, the inclusions were transformed into CaO-Al₂O₃ in the steel. With the progress of smelting, the cleanliness of molten steel became worse, and the equivalent diameter of inclusions was at a higher level. Mg-treatment had a good effect on the modification of inclusions. After Mg-containing cored wire was added to the steel, Al₂O₃ and CaO-Al₂O₃ in the steel were transformed into MgO, MgO·Al₂O₃, and CaO-MgO-Al₂O₃ inclusions, which were basically spherical. The initial precipitated MgO became the core of other inclusions in the steel, which promotes the precipitation of MgO·Al₂O₃. After Mg-treatment, almost no unmodified calcium aluminate inclusions existed in the hot rolled plate, and the cleanliness of the steel was improved. The effect of Ca and Mg on the transformation of inclusions in pipeline steel was studied by thermodynamic calculation, the result of which is consistent with the experimental results.
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  Refinement of cast microstructure of A517 steel by addition of TiB₂

  Guo-fang Liang, Yin-gang Liu, Xian-liang Yang, Qi-yang Tan, Tao Wu, Jian-jun Wang, Andrej Atrens, Zhi-qiang Tian, Ming-xing Zhang

  钢铁研究学报（英文版）. 2024, 31(11): 2815-2827.
  https://doi.org/10.1007/s42243-024-01248-9

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  The effect of TiB2 addition on microstructure refinement of the as-cast and reheated A517 steel has been investigated. 0.1 wt.% TiB₂ addition resulted in a reduction in equiaxed γ grain size from 990 ± 183 to 116 ± 35 lm and an increase in the volume fraction of equiaxedγgrain region from 5% to 67% in the as-cast A517 steel ingots. Microstructure analysis identified TiN particles rather than TiB₂. This is attributed to the low thermodynamic stability of TiB₂, leading to its decomposition into free Ti and B elements at an elevated temperature. Then, chemical reaction between the free Ti and residual nitrogen in the liquid resulted in the formation of TiN. Hence, it is considered that TiN acted as heterogeneous nucleation sites for the d-ferrite. This initiated the refinement and columnar to equiaxed transition of d-dendrites. As a result, the subsequently formedγgrains were correspondingly refined. Such microstructure refinement led to improvement of the yield strength and ultimate tensile strength of the as-cast A517 steel. However, the reheating of the as-cast A517 steel resulted in a marginal microstructure refinement in the samples with low TiB₂ addition. This is attributed to the limited pinning effect of the coarse TiN particles formed during casting process. Consequently, the tensile properties of the reheated A517 steel remained unaffected by the TiB₂ addition.
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  Dynamic recrystallization behavior and finite element analysis of a low-alloy high-strength steel

  Yu-hao Liu, Hao-qing Tang, Guo-ming Zhu, Bao-qiao Wu, Jie Wang, Meng Xia

  钢铁研究学报（英文版）. 2024, 31(11): 2828-2851.
  https://doi.org/10.1007/s42243-023-01160-8

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  The axial single-pass high temperature compression test of a hot-rolled extra-large heavy H-beam steel continuous casting billet (Q420 steel) under different deformation conditions through the Gleeble-1500D thermomechanical simulator was carried out. The modified Johnson-Cook model and the Arrhenius model based on strain-compensated of Q420 steel were established. The latter can more accurately reflect the flow behavior of Q420 steel. For the simulation of thermal compression, dynamic recrystallization (DRX) correlation models were developed and imported into DEFORM-3D software. According to simulation results, high temperatures and low strain rates are conducive to DRX. Due to the uneven distribution of equivalent strain and temperature in different parts of the same section, DRX volume fraction and grain size are unevenly distributed. At the center, the DRX volume fraction is the largest and the grain size is the smallest. The upper and lower edges are vice versa, and the left and right edges are centered. Optical microscopy and electron backscatter diffraction characterization methods were used to study the hot compression microstructure under different deformation conditions. As the deformation amount increases, complete DRX is gradually reached. The original austenite grain gradually becomes smaller. Local average misorientation decreases with the progression of DRX but increases with the amount of deformation after completion of DRX. As the temperature increases and the rate decreases, low angle grain boundaries and medium angle grain boundaries gradually decrease, and high angle grain boundaries gradually increase, indicating that dislocation decreases gradually, DRX grains increase gradually, and martensitic multilayer structure is obvious. As austenite grain size increases, the length of martensite lath increases, and the number of martensite blocks decreases.
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  Corrosion behavior of as-cast Al_0.75CoFeCr_1.25Ni high entropy alloy in 0.5 mol/L NaOH solution

  Si-jia Nie, Xue-ning Yi, Hui-ling Zhou, Hao-jie Zhu, Lan-lan Yang, Fang-lian Fu, Jing-yong Li, Hao-kun Yang, Guo-xiang Xu, Sheng Lu, Yan-xin Qiao

  钢铁研究学报（英文版）. 2024, 31(11): 2852-2863.
  https://doi.org/10.1007/s42243-024-01180-y

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  The corrosion behavior of an Al_0.75CoFeCr_1.25Ni high-entropy alloy (HEA) in 0.5 mol/L NaOH solution was investigated using a series of electrochemical and analytical techniques, including X-ray photoelectron spectroscopy, X-ray diffraction, scanning electron microscopy, potentiodynamic polarization measurement and electrochemical impedance spectroscopy. The results showed that the Al_0.75CoFeCr_1.25Ni HEA exhibited a typical columnar dendritic structure, which is composed of face-centered cubic, body-centered cubic (BCC), and ordered BCC phases (B2 phase). The corrosion resistance of this HEA in 0.5 mol/L NaOH solution is comparable to that of 304 SS, attributed to the change in the composition of the passive film formed on the surface. Although the passive film formed was generally rich in Al, the proportion of Cr₂O₃ inside it increased with the increasing immersion time, enhancing the stability of the passive film and thus improving the corrosion performance of this HEA in 0.5 mol/L NaOH solution.
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  Synergistic action of erosion-corrosion on L360N in different condensate oil-contained NaCl solutions

  Yan-ran Wang, Hai-feng Liu, Hong-fa Huang, Xiao-xiong Guo, Lin-cai Peng, Chang-hui Zhang

  钢铁研究学报（英文版）. 2024, 31(11): 2864-2878.
  https://doi.org/10.1007/s42243-024-01199-1

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  The experiments studying on the components of pure erosion, pure corrosion and their synergism were performed in multiphase systems containing sand particles, NaCl solution and condensate oil. The influence of condensate oil content on damage degree for each component was investigated by designing four different levels (0, 5, 10 and 20 vol.%). The mechanism about erosion-corrosion was analyzed by measurements of thinning rate, electrochemical experiments, scanning electron morphology and white light interferometer. The results showed that the presence of condensate oil enhanced mechanical damage of L360N pipeline steel because of the increase in viscosity. The erosion-corrosion and pure erosion were significantly accelerated with the increase in condensate oil content. However, the condensate oil content had basically no effect on pure corrosion, and the thinning rate for it was much lower than that for pure erosion. Therefore, the pure erosion component dominated the erosion-corrosion damage in such multiphase systems.