《钢铁》第一届青年编委介绍（二）

1、板带轧制三维塑性变形理论；

2、板带材轧制与精整过程产品质量（板形、断面形状、表面质量）检测与控制；

3、板带轧制过程智能化理论与技术。

[1] 徐扬欢，王东城，汪永梅，等. 基于自编码器的冷轧带材板形数据降维方法[J]. 钢铁，2021，56(9)：26-35.

[2] 王东城，徐扬欢，于华鑫，等. 整辊内嵌式板形仪挠度干扰信号的消除方法[J]. 钢铁，2020，55(10)：56-62.

[3] 王东城，张亚林，徐扬欢. 热轧带钢尾部“伪板形不良”问题研究[J]. 钢铁，2020，55(9)：64-68.

[4] 王东城，徐扬欢，段伯伟，等. 数据驱动的热轧带钢边部线状缺陷智能预报模型[J]. 钢铁，2020，55(11)：82-90.

[5] 于华鑫，王东城，刘宏民，等. 冷轧带材整辊式板形仪通道耦合与解耦[J]. 钢铁，2019，54(11)：63-68.

[6] 于华鑫，王东城，刘宏民，等. 冷轧带材板形辊传动方案设计[J]. 钢铁，2019，54(7)：56-60.

[7] Xu Yang-huan，Wang Dong-cheng，Liu Hong-min，et al. Flatness defect recognition method of cold rolling strip with a new stacked generative adversarial network[J]. Steel Research International，2022，93(11)：2200284.

[8] Wang Dong-cheng，Xu Yang-huan，Zhang Tong-yuan，et al. Formation Mechanism and Control Strategy of Edge Seam Defects for Hot Rolling Interstitial-Free Steel[J]. Steel Research International，2022，93(5)：2100495.

[9] Wang Dong-cheng，Xu Yang-huan，Zhang Tong-yuan，et al. Quantitative study on the relationship between the transverse thickness difference of cold-rolled silicon strip and incoming section profile based on the mechanism-intelligent model[J]. Metallurgical Research & Technology，2021，118(3)：303.

[10] Yu Hua-xin，Wang Dong-cheng，Liu Hong-min，et al. Modelling and Application of Signal Decoupling of Adjacent Channels of a Whole-Roller Seamless Flatness Meter[J]. ISIJ International，2020，60(5)：939-947.

[1] 张静，马宏博，张继，张立峰. 钇含量对铝脱氧含钛不锈钢中夹杂物的影响[J]. 钢铁，2022，57 (9):82-94.

[2] 刘瀚泽，张静*，张继，张立峰，盖彦峰. 稀土元素铈对钢中非金属夹杂物改性和腐蚀影响的第一性原理研究[J].工程科学学报，2022，44 (9):1516-1528.

[3] Zhang Jing, Su Chun-ming, Chen Xian-pei, Liu Han-ze, Zhang Li-feng. First-principles study on pitting corrosion of Al deoxidation stainless steel with rare earth element (La) treatment[J]. Materials Today Communications，27 (2021) 102204.

[4] Chun-ming Su, Jing Zhang*. First-principles study on growth mechanism of TiN on MgO (100) and (110) surfaces [J]. Computational Materials Science，189(2021)110257.

[5] Jing Zhang, Chun-ming Su, Yong Liu.First-principles study of bcc Fe-Cr-Si binary and ternary random alloys from special quasi-random structure[J]. Physica B: Physics of Condensed Matter，586 (2020) 412085.

[6] Jing Zhang, Yun-Peng Zhang, Chun-Ming Su. First-principles study of FeNi1-xCrx  (0≤x≤1) disordered alloys from special quasirandom structures[J].CALPHAD: Computer Coupling of Phase Diagrams and Thermochemistry, 71 (2020) 102007.

[7] 张静, 马靓, 赵登飞.大方坯结晶器电磁搅拌器结构优化研究[J]. 中国机械工程, 2020,31(10): 1-7.

[8] 张静，马靓，吴会平.水口结构对连铸中低碳钢流场和温度场的影响[J].钢铁，2019,54（8）:116-123. 

先进钢铁材料。

[1] 杨志南，张福成.钢中贝氏体：理论与实践，译著，燕山大学出版社，2020.

[2] 张福成，杨志南.贝氏体中残余奥氏体，专著，燕山大学出版社，2019.

[3] 王耀民，姜锋，王庆超，闫学峰，杨志南*，张福成. 层数变化对马氏体-奥氏体复合钢组织和性能的影响 [J]. 钢铁，2022，57（11）:113-122.

[4] 尤蕾蕾，王红伟，侯俊，李雪梅，杨志南*，G8Cr15轴承钢的工业化应用分析 [J]. 中国冶金，2020, 30(9): 91-97,128.

[5] Z.N. Yang*, F. Jiang, Y.M. Wang, Q.C. Wang, M.X. Huang, Y.F. Wang, C. Chen*, F.C. Zhang*. Making composite steel higher strength and higher ductility via introducing carbon diffusion strategy [J]. Mater. Res. Lett., 2021, 9(9): 391-397.

[1] 满廷慧，刘坤，江畅，彭伟，刘腾轼，董瀚.中国百年钢轨钢的微观组织 [J]. 钢铁， 57(12) (2022) 1-10.

[2] 满廷慧, 江畅, 刘坤, 刘腾轼, 顾金才, 董瀚.大截面高强度中锰锻钢淬透性研究 [J]. 钢铁研究学报，34(8) (2022) 834-839.

[3] Ting-hui MAN, Yi-hao ZHOU, Nan DONG, Teng-shi LIU, Han DONG. Microstructural evolution of the rail steels manufactured by Hanyang Iron Works [J]. Materials, 15 (2022) 5488.

[4] Wei-jun WANG*, Ting-hui MAN*, Mei ZHANG, Yang WANG, Han DONG. δ-ferrite dynamic recrystallization behavior during thermal deformation in Fe-32Mn-11Al-0.9C low density steel [J]. Journal of Materials Research and Technology, 18 (2022) 1345-1357.

[5] Ting-hui MAN, Chun-dong HU, Heng-chang LU, Yue-wei CHEN, Yuan LIN, Han DONG. Effect of annealing temperature on microstructure and hardness of Ni-Co alloy coating [J]. Materials Today Communications, 31 (2022) 103244.

[6] Ting-hui Man*, Wei-jun Wang, Yi-hao Zhou, Teng-shi Liu, Heng-chang Lu, Xiu-ming Zhao, Mei Zhang, Han Dong. Effect of cooling rate on the precipitation behavior of κ-carbide in Fe-32Mn-11Al-0.9C low density steel [J]. Materials Letters, 314 (2022) 131778.

[7] 满廷慧, 彭伟, 王子波, 廉心桐, 陆恒昌, 董瀚. Fe-Mn-Al-C低密度钢研究现状及展望 [J]. 中国冶金，32(1) (2022) 11-20.

[8] Ting-hui Man, Takahito Ohmura, Yo Tomota. The effect of boundary or interface on stress-induced martensitic transformation in a Fe-Ni alloy [J]. Materials Today Communications, 23 (2020) 100896.

[9] Ting-hui MAN, Takahito OHMURA, Yo TOMOTA. Mechanical Behavior of Individual Retained Austenite Grains in High Carbon Quenched-tempered Steel [J]. ISIJ International, 59(3) (2019) 559-566.

[10] T.H. Man, T.W. Liu, D.H. Ping, T. Ohmura. TEM investigations on lath martensite substructure in quenched Fe-0.2C alloys [J]. Materials Characterization, 135 (2018) 175-182.

炼钢精炼与连铸新技术；高压特种冶金工艺及含氮合金粉体制备；复杂结构件SLM熔凝过程控制与增材制造新技术；高品质洁净钢（不锈钢、高速钢等）夹杂物控制。

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[5]  Liu, Yan, Ding-guo Zhao*, Yue Li, Shu-huan Wang. Effects of Nano TiC on the Microhardness and Friction Properties of Laser Powder Bed Fusing Printed M2 High Speed Steel[J]. Coatings, 2022, 12(6): 825.

[6]  Xiao-jie Cui, Yue-kai Xue, Ding-guo Zhao*, Shu-huan Wang, Fu-jian Guo. Physical modeling of bubble behaviors in molten steel under high pressure[J]. High Temperature Materials and Processes, 2021, 40(1): 471.

[7]  D. G. Zhao, Y. F. Wang, M. Gao, S. H. Wang, S. P. Cui. Experimental Study on Inclusion Absorbed by Absorption Bar in Liquid Steel[J]. Ironmaking & Steelmaking, 2019, 46(3): 235.

[8]  Z. DING-GUO, G. MING. W. SHU-HUAN, L. XIN. Collision and Absorption Behaviours of Inclusions on Refractory[J]. Archives of Metallurgy and Materials, 2017, 62(2): 857.

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[1] 刘然 , 张智峰 , 刘小杰 , 李欣 , 李宏扬 , 吕庆 . 低碳绿色炼铁技术发展动态及展望 [J].   钢铁 , 2022, 57(5): 1-10.

[2] Chen-chen Lan, Ran Liu, Shu-hui Zhang, Qing Lyu, Yan-jia Gao, Guang-shi Yan. Influence mechanism of CaO on gasification characteristics and kinetic behaviors of carbon-CO2 reaction[J]. Fuel, 2022, 311(3): 122583.

[3] Yong Deng, Ran Liu, et al. Application bottleneck and optimization of big data technology in blast furnace ironmaking[J]. Iron & Steel Technology, 2022, 10:1-9.

[4] 张智峰, 刘小杰, 李欣, 吕庆, 陈树军, 刘然. 基于MIV-GA-BP模型预测烧结矿FeO含量[J]. 中国冶金, 2022, 32(10): 75-81.

[5] 兰臣臣, 张淑会, 刘然, 吕庆, 李福民. N2-CO-CO2-H2O气氛下K(g)对焦炭高温气化反应动力学的影响[J]. 中国冶金, 2022, 32(7):12-19.

[6] Yong Deng, Ran Liu, Ke-xin Jiao, Li-da Chen, Yan-bo Chen. Evolution and mechanism of dissolutive wetting between hot metal and carbon brick[J]. J. Eur. Ceram. Soc., 2022, 42: 4420.

[7] Chen-chen Lan, Shu-hui Zhang, Xiao-jie Liu, Ran Liu, Qing Lyu. Kinetic behaviors of coke gasification with CO2 and H2O[J]. ISIJ Int., 2021, 61(1): 167-173.

[8] Yong Deng, Jian‑liang Zhang, Ran Liu, Ke‑xin Jiao, Bing‑ji Yan. Smelting practice of scrap addition in blast furnace and theoretical analysis of cost saving[J]. J. Iron Steel Res. Int., 2020, 27(9): 1005.

[9] 兰臣臣, 刘然, 张淑会, 吕庆. 高炉内H2体积分数对焦炭气化反应的影响[J]. 钢铁, 2020, 55(8): 100-106.

[10] 邓勇, 刘然, 刘小杰, 李澳淼, 李涛. 炉缸炭砖侵蚀过程及基于AHP的界面反应调控[J]. 钢铁, 2020, 55(8): 100-106.

[1] Yao-zong Shen, Kai Zhao * ,  Qiao-rong Zhang, Chang-liang Zhen & Yuan-hong Qi. Physical simulation of macroinstability behaviour of liquid level in oxygen coal combustion melting and separation furnace [J]. Ironmaking & Steelmaking, 2022, 49(11): 1-19.

[2] Shen Yao zong, Zhao Kai*, Kong Zheng, Zhang Yu zhu, Shi Yan, Qi Yuan hong. Three-dimensional numerical simulation of velocity field distribution in an oxy-coal combustor-melter-separator furnace[J]. Metallurgical Research & Technology, 2021, 118(5): 510-524.

[3] Zhao K*,  Shen Y Z ,  Kong Z , et al. Three-dimensional numerical simulation of flow and splash behavior in an oxygen coal combustion melting and separating furnace[J]. Journal of Iron and Steel Research International, 2021, 28: 965-977.

[4]张晓华，赵凯（通讯），白庚琛，张玉柱，高建军，张颖异. 多约束条件下回转窑-氧煤燃烧熔分炉热工分析[J]. 钢铁，2020，55（3）：9-15.

[5]赵凯，魏志芳，张巧荣，张玉柱，王彬，申耀宗. 氧煤燃烧熔分炉炉料沉降与传热行为数值模拟[J]. 钢铁，2021，56（11）：19-29.

[6]甄常亮，于恒，赵凯（通讯），韩伟刚，师学峰. 基于界面技术的钢渣热态转运路径优化[J]. 钢铁，2021，56（8）：119-124.

[7] 张兴华，王彬，赵凯（通讯），张巧荣，宫晓然，邢宏伟. 高硅铁废渣直接还原铁晶粒形成与长大[J]. 钢铁，2021，56（6）：21-27 .

[1]   De-min Chen,  Jia-qi Li, Zhao Wang, Biao Lu*, Guang Chen.Hierarchical model to find the path reducing CO2 emissions of integrated iron and steel production[J]. Energy，2022,258,124887.

[2]Biao Lu, Kai Tang, De-min Chen *, Yun-long Han, Suo-jun Wang, Xin He, Guang Chen. A Novel Approach for Lean Energy Operation Based on Energy Apportionment Model in Reheating Furnace [J] . Energy，2019,182:1239.

[3]De-min Chen, Biao Lu, Fang-Qin Dai*, Guang Chen, Xi-he Zhang. Bottleneck of slab thermal efficiency in reheating furnace based on energy apportionment model [J] . Energy，2018, 150: 1058.

[4]De-min Chen, Biao Lu, Fang-Qin Dai*, Guang Chen, Wei-ping Yu. Variations on billet gas consumption intensity of reheating furnace in different production states [J] . Applied Thermal Engineering，2018, 129:1058. 

[5]De-min Chen, Biao Lu*, Xi-he Zhang, Fang-qin Dai, Guang Chen, Ying-jie Liu. Fluctuation characteristic of billet region gas consumption in reheating furnace based on energy apportionment model [J] . Applied Thermal Engineering，2018, 136: 152-160.

[6]Biao Lu, Yi-bo Zhao, De-min Chen *, Jia-qi Li, Kai Tang. A novelty data mining approach for multi-influence factors on billet gas consumption in reheating furnace [J] . Case Studies in Thermal Engineering，2021,26: 101080.

[7] De-min Chen, Hao-wen Xu, Biao Lu*, Guang Chen**, Lu Zhang. Solving the Heat Transfer Boundary Condition of Billet in Reheating Furnace by Combining “Black box” Test with Mathematic Model[J].Case Studies in Thermal Engineering, 2022, 40, 102486.

[8]Chen,D.M.,Liu,Y.H.,He,S.F.,Xu, S.,Dai, F.Q.,Lu, B*. Fuel Gas Operation Management Practices for Reheating Furnace in Iron and Steel Industry [J] . Advances in Production Engineering & Management，2020, 15(2):179-191.

[9]Chem,D., Lu, B*.,Chen G., Yu, W. Influence of the production fluctuation on the process energy intensity in iron and steel industry [J] . Advances in Production Engineering & Management，2017, 12(1):75-87.

[10]De-min Chen *, Zi-huai He,Yi-bo Zhao, Biao Lu. A novel Acquisition on Approach for Heat Transfer Coefficient During Periodic Cooling Process [J] . Thermal Science，2022. 26(4A), 3097-3106.

[11]陈德敏, 刘莹惠, 陆彪,等. 层流冷却传热系数对金属物料温度场的影响[J]. 过程工程学报, 2021, 21(9): 1033.