2019年, 第26卷, 第11期　刊出日期：2019-11-25

  

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  Numerical model of inclusion separation from liquid metal with consideration of dissolution in slag

  Wei Liu, Shu-feng Yang, Jing-she Li, Feng Wang, Hong-bo Yang

  钢铁研究学报(英文版). 2019, 26(11): 1147-1153.
  https://doi.org/10.1007/s42243-018-0212-2

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  The transport of inclusion particles through the liquid metal/molten slag interface and their dissolution in the slag are two key processes of inclusion removal. Based on the latest version of inclusion transport model that takes into account full Reynolds number range and a dissolution kinetics model, a coupled model was developed to simulate the whole process of inclusion removal, from floating in the liquid steel to crossing the interface and further to entering and dissolving in the molten slag. The interaction between the inclusion motion and dissolution was discussed. Even though the inclusion velocity is a key parameter for dissolution, the simulation results show no obvious dissolution during moving state because the process is too short and most of the inclusions dissolve during its static stay in the slag side above the interface. The rate-controlling step of inclusion removal is the transport through the steel–slag interface for the small-size inclusion and static dissolution above the interface for the large-size inclusion, respectively.
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  Coupling efect and characterization modeling of iron ore fnes mixing and granulating at 0–1 mm

  Dai?fei Liu, Xian?ju Shi, Chao?jun Tang, Hai?peng Cao, Jun Li

  钢铁研究学报(英文版). 2019, 26(11): 1154-1161.
  https://doi.org/10.1007/s42243-019-00330-x

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  Characteristic of iron ore is the essential factor of granulating. Three ores, namely specularite, magnetite concentrate and limonite, were selected as adhesion powder to investigate granulating behavior and evolution process of agglomeration. Experiments and modeling were performed to represent granulating behavior on the basis of selectivity, ballability and adhesion rate. The mass fraction of water and particles size of adhesion and nucleation were set at (11 ± 1)%, 0–1 mm and 3–5 mm, respectively. Experimental results show that selectivity and ballability promote the evolution of granulation. The water absorption rate of specularite and the ballability of limonite are better. The coupling efects exist in two ores mixing and present positive efect when the proportion of magnetite concentrate is greater than that of specularite or specularite and limonite blend. During three ores mixing, the coupling efect presents a complex superposition state. A characterization model of adhesion rate of mixing granulation was established by random forest algorithms. Its output is adhesion rate, and its inputs include water absorption rate, balling index and mixing proportion. The model parameters are 957 trees and four branches, and the training and prediction errors of the model are 2.3% and 3.7%, respectively. Modeling indicates that the random forest model can be used to represent coupling efects of mixing granulation.
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  Distribution of P2O5 between solid solution and liquid phase in dephosphorization slag of CaO–SiO2–FeO–P2O5–Na2O system

  Chuan-ming Du, Ning-ning Lv, Chang Su, Wei-ming Liu, Jin-xing Yang, Hai-chuan Wang

  钢铁研究学报(英文版). 2019, 26(11): 1162-1170.
  https://doi.org/10.1007/s42243-018-00224-4

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  A multi-phase slag containing Na2O is potential to efficiently dephosphorize high-P hot metal. After dephosphorization, the generated slag with high P2O5 content is regarded as a P resource. Because P2O5 was mainly concentrated in the 2CaO SiO2–3CaO P2O5 solid solution, the recovery of P from dephosphorization slag primarily depends on the separation of the solid solution from other phases. The distribution ratios of P2O5 between solid solution and liquid phase in the CaO– SiO2–FeO–P2O5–Na2O slag system were investigated. The results indicated that the addition of Na2O facilitated the enrichment of P2O5 in the solid solution because it increased not only the distribution ratio of P2O5 but also the mass fraction of the solid solution. The distribution ratio of P2O5 was independent of the P2O5 content in slag. A higher P2O5 content in slag resulted in higher P2O5 and Na2O contents in the solid solution. The distribution ratio of P2O5 increased with the total Fe content in the liquid phase, regardless of the valence of Fe. An increase in the FeO content in slag brought a higher P2O5 content in the solid solution. As slag basicity increased, the distribution ratio of P2O5 increased, but the P2O5 content in the solid solution decreased.
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  Fundamental mechanism of effects of MgO on sinter strength

  Hong-song Han, Feng-man Shen, Xin Jiang, Chuan-guang Bi, Hai-yan Zheng, Qiang-jian Gao

  钢铁研究学报(英文版). 2019, 26(11): 1171-1177.
  https://doi.org/10.1007/s42243-019-00331-w

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  MgO-containing flux may have a series of effects on the quality of sinter and performances of the blast furnace. Thus, the fundamental mechanism of the effects of MgO on the sinter strength was investigated. Both the chemical reagent and industrial flux were used for preparing the specimens. The experimental results show that the sinter strength decreases with MgO addition. There are three reasons for it. The first reason is diffusion rate. Almost all of the CaO may react with Fe2O3 and generate CaO Fe2O3, but most of MgO cannot react with Fe2O3, and it still remains in the state of original minerals. The diffusion rate of MgO in iron oxide is only 17.51 lm/min in 30 min. The second reason is the fluidity and ability to generate liquid phase. In the case of Fe2O3 mixed with CaO, there is some liquid phase formed above 1200 C, while in the case of Fe2O3 mixed with MgO, even at 1200 and 1220 C, there is still no liquid phase. The third reason is self-strength. In the case of industrial flux, the compression strength of the specimens made of Fe2O3 and limestone is 0.52 and 0.71 kN at 1150 and 1180 C, respectively, while that of the specimens made of Fe2O3 and magnesite is 0.48 and 0.56 kN, respectively. Therefore, the fundamental mechanism of the effects of MgO additive on sinter strength can be better understood based on the diffusion rate of MgO in iron oxides, the fluidity of liquid phase, and the self-strength of bonding phase.
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  Deformation mechanism analysis of roll forming for Q&P980 steel based on finite element simulation

  Fei Han, Yun Wang, Li-li Niu

  钢铁研究学报(英文版). 2019, 26(11): 1178-1187.
  https://doi.org/10.1007/s42243-019-00243-9

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  Roll forming is a sheet metal forming process, which can form the profiles gradually to improve the formability of Q&P980 steel. The plastic deformation mechanism of roll forming was expounded by analysing the stress and strain distribution at the corner of a hat-type profile when the Q&P980 steel sheet passed through a series of continuous stands. And the plastic deformation mainly accumulated when the sheet metal was not in contact with the rolls. A simple mathematical model was derived by considering the longitudinal bending strain and the geometrical relationships of forming parameters, to analyse the longitudinal strain development in the deformation process. In addition, the roll forming experiments on hat-type profile parts of Q&P980 steel were carried out, and the theoretical analysis and simulation results are consistent with the experimental results.
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  Combination of cold drawing and cryogenic turning for modifying surface morphology of metastable austenitic AISI 347 steel

  Hendrik Hotz, Benjamin Kirsch, Steven Becker, Ralf Mu¨ ller, Jan C. Aurich

  钢铁研究学报(英文版). 2019, 26(11): 1188-1198.
  https://doi.org/10.1007/s42243-019-00306-x

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  The application of components often depends to a large extent on the properties of the surface layer. A novel process chain for the production of components with a hardened surface layer from metastable austenitic steel was presented. The investigated metastable austenitic AISI 347 steel was cold-drawn in solution annealed condition at cryogenic temperatures for pre-hardening, followed by post-hardening via cryogenic turning. The increase in hardness in both processes was due to strain hardening and deformation-induced phase transformation from c-austenite to a0-martensite. Cryogenic turning experiments were carried out with solution annealed AISI 347 steel as well as with solution annealed and subsequently cold-drawn AISI 347 steel. The thermomechanical load of the workpiece surface layer during the turning process as well as the resulting surface morphology was characterized. The forces and temperatures were higher in turning the cold-drawn AISI 347 steel than turning the solution annealed AISI 347 steel. After cryogenic turning of the solution annealed material, deformation-induced phase transformation and a significant increase in hardness were detected in the near-surface layer. In contrast, no additional phase transformation was observed after cryogenic turning of the cold-drawn AISI 347 steel. The maximum hardness in the surface layer was similar, whereas the hardness in the core of the cold-drawn AISI 347 steel was higher compared to that in the solution annealed AISI 347 steel.
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  Influence of inclusions on hydrogen-induced delayed cracking in hot stamping steels

  Yong Chen, Jing Liu, Feng Huang, Ling Chen, Yan-jing Su, Gui-feng Zhou

  钢铁研究学报(英文版). 2019, 26(11): 1199-1208.
  https://doi.org/10.1007/s42243-019-00312-z

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  The hydrogen-induced delayed cracking (HIDC) behaviors of two types of 1500 MPa grade hot stamping steels (HSSs) have been investigated by the method of slow strain rate tensile test and hydrogen permeation, where one is manufactured by compact strip production (CSP) process which is a revolution to the traditional HSS and the other by the traditional cold rolling process. The results show that the performance of HSS produced by CSP is superior to that of the traditional HSS, due to lower hydrogen embrittlement index, lower hydrogen diffusion coefficient and lower hydrogen content. It has been found that HIDC behavior is closely associated with inclusions. The inclusions of HSS produced by CSP are mainly spherical Al–Ca–O and CaS, while the inclusions in the traditional HSS are TiN 1 Al2O3 ? MnS with sharp edges and corners. Based on these results, the influence of composition, shape and distribution of inclusions in HSS on HIDC and the mechanism of HIDC from the perspective of inclusions were analyzed and discussed.
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  Effect of volume fraction and mechanical stability of austenite on ductility of medium Mn steel

  Si-lian Chen, Zhao-xi Cao, Chang Wang, Chong-xiang Huang, Dirk Ponge, Wen-quan Cao

  钢铁研究学报(英文版). 2019, 26(11): 1209-1218.
  https://doi.org/10.1007/s42243-019-00267-1

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  A hot-rolled medium Mn (0.2C5Mn) steel is annealed at 650 C to produce an ultrafine-grained duplex microstructure with different austenite volume fractions by austenite reverted transformation (ART) annealing, and the orientation relationship strictly obeys K–S orientation relationship before deformation. Tensile tests are carried out in a temperature range from - 196 to 400 C to examine the effects of the austenite volume fraction and the deformation temperature on the tensile properties and the austenite stability. Microstructural observations reveal that the metastable austenite gradually transformed into a-martensite, which is controlled by the deformation strain, the temperature and the austenite volume fraction. Both strain hardening behavior and ductility of the studied steel are dependent on austenite volume fraction and deformation temperature significantly. The stress–strain curves of ART-annealed 0.2C5Mn steel assume an S shape and a very large work hardening rate of about 10 GPa is obtained at liquid nitrogen deformation temperature. Based on the experimental data, a quantitative relation is proposed to describe the ductility dependence on both the austenite volume fraction and its mechanical stability.
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  Effect of normalization on texture evolution of 0.2-mm-thick thingauge non-oriented electrical steels with strong g-fiber textures

  Jing Qin, De-fu Liu, Ye Yue, Hong-jin Zhao, Chao-bin Lai

  钢铁研究学报(英文版). 2019, 26(11): 1219-1227.
  https://doi.org/10.1007/s42243-018-00222-6

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  Thin-gauge non-oriented electrical steel sheets of 0.2 mm in thickness with high magnetic induction and low core loss were produced by a two-stage cold-rolling method with and without normalization annealing. The through-process texture evolutions of the two processes were compared and studied by means of X-ray diffractometer and electron backscattered diffraction. Results showed that excellent magnetic properties were attributed to strong g-fiber recrystallization texture in the final sheet. Coarse c-fiber-oriented grains after intermediate annealing and medium cold-rolling reduction were considered key factors to obtain a strong g-fiber texture given that a large number of shear bands within the c-fiber deformed matrix provided dominant nucleation sites for g-fiber-oriented grains. The normalization annealing after hot rolling was favorable for the retention of cube texture, thereby decreasing the magnetic anisotropy of thin-gauge non-oriented electrical steels.
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  Microstructural evolution and constitutive models of 9CrMoCoB heatresistant steel during high-temperature deformation

  Chao-hang Jia, Chen-xi Liu, Yong-chang Liu, Chong Li, Hui-jun Li

  钢铁研究学报(英文版). 2019, 26(11): 1228-1239.
  https://doi.org/10.1007/s42243-019-00273-3

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  In order to research the hot deformation behavior of 9CrMoCoB heat-resistant steel, hot compression tests were performed over a wide range of temperatures from 850 to 1150 C and strain rates from 0.01 to 10.00 s-1. The flow stress appears to increase with the decrease in deformation temperature and the increase in strain rate. The relationship between microstructural evolution and deformation parameters was studied, indicating that both low strain rate and high deformation temperature appear to promote the dynamic recrystallization, while excessively high temperature with low strain rate would result in the high non-uniformity of grain size. The experimental stress–strain data was applied to calculate the material constants involved in the Arrhenius-type constitutive model and the modified Zerilli-Armstrong (MZA) model, and feasibility of these two models was evaluated. The results show that the MZA model is more accurate to predict the high-temperature flow behavior of the experimental steel than the Arrhenius-type constitutive equation.
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  Nanoscratching and mechanical behaviors of high-entropy alloys with different phase constituents

  Jiang-li Ning, Yun-li Feng, Xu-dong Li, Qi-bo Deng, Yong-jiang Huang

  钢铁研究学报(英文版). 2019, 26(11): 1240-1248.
  https://doi.org/10.1007/s42243-019-00329-4

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  High-entropy alloys (HEAs) exhibit unique microstructural features and properties in nanoscale and atomic scale because of their multi-element alloy system. The nanoscratching behaviors of three HEAs with different phase constituents, relative to the microstructure and mechanical properties of the HEAs, were investigated. Three typical phase constituents were selected: face-centered cubic (FCC) structure, body-centered cubic (BCC) structure, and a dual-phase structure containing both FCC and BCC phases. Despite the fact that the FCC alloy has the highest ductility and strain hardening capability, it exhibited inferior scratch resistance due to the over-softening of hardness. Due to the brittle failure mode, the BCC alloy hardly exhibited desirable scratch resistance despite its highest hardness. By contrast, the nanostructured dual-phase alloy exhibited the best scratch resistance because of its good combination of strength and ductility, as well as the ductile failure mode. This research suggests that the HEA with structure comprising nanoscale hard and soft phases is desirable for nanoscratch resistance, and possesses appropriate hardness for industrial applications.
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  Microstructure and mechanical properties of low carbon steel wires with serial and reverse-direction cold drawing

  Li-chu Zhou, Meng-yuan Xia, Xue-gang Min, Feng Fang

  钢铁研究学报(英文版). 2019, 26(11): 1249-1256.
  https://doi.org/10.1007/s42243-019-00310-1

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  Low carbon steel wires were prepared by two processes, serial drawing (SD) and reverse-direction drawing (RD). Effects of the two processes on microstructure and mechanical properties in steel wires were investigated by field emissionscanning electron microscopy, electron backscatter diffraction (EBSD), X-ray diffraction and transmission electron microscopy (TEM). Residual compressive stress and more low-angle grain boundaries were introduced into the steel wire by the RD. As a result, the RD wires exhibited a greater tensile strength when drawing strain e \ 1.18. The SD encouraged grain refinement and texture formation in the wire. The SD wires exhibited a smaller average width of the elongated ferrite grain and a higher intensity of h110i fiber texture at all drawing strains. Therefore, the SD wires showed a bit greater tensile strength and 20% greater torsion performance than the RD wires at e = 2.51. TEM and EBSD analysis indicated that dislocation tangle was formed easily in RD wires, and it transformed into twist boundary. This twist boundary impeded the grain refinement in the RD wires, and there were still non-fibrous grains in the RD wires even after heavy drawing.