Twin-roll strip casting of advanced metallic materials 被引量：2

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摘要 Metallic materials have historic and served as critical enablers of human progress,wealth,and wellbeing over millennia.Recently,the global demand for the development of environment-friendly and energy-saving technology has been increasing,with the aim to support the sustainability of metallic materials.Twin-roll strip casting(TRC)is one of the most cutting-edge technologies and a near-net-shape manufacturing method in the steel industry,which conforms to the green fabrication trend of next-generation high-performance metallic materials.By utilizing the dominant characteristics of sub-rapid solidification,and integration of solidification,solid-state transformation,and deformation;TRC has become a meaningful way to deal with the most challenging issues in the processing of metallic materials,and made a significant contribution to materials manufacturing.Hence,we review the TRC process of various metallic materials,including plain carbon steels,stainless steels,Fe-Si electrical steels,high-strength steels,clad steels,aluminum alloys,magnesium alloys,metallic glasses,and so on.This paper offers an outlook of future opportunities for various advanced metallic materials development through the TRC process,and inspires more in-depth research.

作者 ZHU ChenYang ZENG Jie WANG WanLin

机构地区 School of Metallurgy and Environment National Center for International Research of Clean Metallurgy Department of Materials Science and Engineering

出处《Science China(Technological Sciences)》 SCIE EI CAS CSCD 2022年第3期493-518,共26页 中国科学（技术科学英文版）

基金 supported by the National Natural Science Foundation of China(Grant Nos.U1760202,51904345) Hunan Provincial Key Research and Development Program(Grant No.2018WK2051) the State Scholarship Fund from the China Scholarship Council(Grant No.201906370153)。

关键词 twin-roll strip casting metallic materials STEELS ALLOYS

分类号 TG249.7 [金属学及工艺—铸造]

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参考文献9

1张卫,于艳,方园,李建国.Determination of Interfacial Heat Flux of Stainless Steel Solidification on Copper Substrate During the First 0.2 s[J].Journal of Shanghai Jiaotong university(Science),2011,16(1):65-70. 被引量：2
2Jing Guo,Yuan-yuan Liu,Li-gang Liu,Yue Zhang,Qing-xiang Yang.3D stress simulation and parameter design during twin-roll casting of 304 stainless steel based on the Anand model[J].International Journal of Minerals,Metallurgy and Materials,2014,21(7):666-673. 被引量：3
3董瀚.2020年:合金钢200周年--“合金钢专刊”前言[J].金属学报,2020,56(4). 被引量：6
4Yunbo Xu,Haitao Jiao,Yuanxiang Zhang,Feng Fang,Xiang Lu,Yang Wang,Guangming Cao,Chenggang Li,R.D.K.Misra.Effect of pre-annealing prior to cold rolling on the precipitation,microstructure and magnetic properties of strip-cast non-oriented electrical steels[J].Journal of Materials Science & Technology,2017,33(12):1465-1474. 被引量：3
5Xiang Lu,Yun-Bo Xu,Feng Fang,Yuan-Xiang Zhang,Yang Wang,Hai-Tao Jiao,R.D.K.Misra,Guang-Ming Cao,Cheng-Gang Li,Guo-Dong Wang.Characterization of Microstructure and Texture in Grain-Oriented High Silicon Steel by Strip Casting[J].Acta Metallurgica Sinica(English Letters),2015,28(11):1394-1402. 被引量：2
6余琨,熊汉青,戴翌龙,滕飞,范素峰,乔雪岩,文利.超声波作用下双辊铸轧镁合金板带材的力学性能和成形能力（英文）[J].稀有金属材料与工程,2017,46(3):622-626. 被引量：2
7Long Zhang,Yi Wu,Shidong Feng,Wen Li,Hongwei Zhang,Huameng Fu,Hong Li,Zhengwang Zhu,Haifeng Zhang.Rejuvenated metallic glass strips produced via twin-roll casting[J].Journal of Materials Science & Technology,2020(3):73-79. 被引量：4
8Mang XU,Guo-huai LIU,Tian-rui LI,Bing-xing WANG,Zhao-dong WANG.Microstructure characteristics of Ti-43Al alloy during twin-roll strip casting and heat treatment[J].Transactions of Nonferrous Metals Society of China,2019,29(5):1017-1025. 被引量：5
9王存宇,常颖,周峰峦,曹文全,董瀚,翁宇庆.高强度高塑性第三代汽车钢的M^3组织调控理论与技术[J].金属学报,2020,56(4):400-410. 被引量：33

二级参考文献73

1LI Lin 1,GAO Yi 2,SHI Wen 1,LIU Ren-dong 2,HE Yan-lin 1,FU Ren-yu 1,ZHANG Mei 1,WANG Hua 1 (1.School of Materials Science and Engineering,Shanghai University,Shanghai 200072,China,2.Ansteel Company,Anshan 114001 China,Corresponding Author:School of Materials Science and Engineering,Shanghai University,P.O.Box 15,149 Yanchang Road,Shanghai 200072,China).Martensite Transformation and Its Control in DP,TRIP and TWIP Steels[J].Journal of Iron and Steel Research International,2011,18(S1):200-207. 被引量：1
2李宝辉,孔凡涛,陈玉勇.Effect of Yttrium Addition on Microstructures and Room Temperature Tensile Properties of Ti-47Al Alloy[J].Journal of Rare Earths,2006,24(3):352-356. 被引量：13
3Ning ZHONG,Xiaodong WANG,Yonghua RONG,Li WANG.Interface Migration between Martensite and Austenite during Quenching and Partitioning (Q&P) Process[J].Journal of Materials Science & Technology,2006,22(6):751-754. 被引量：19
4徐祖耀.钢热处理的新工艺[J].热处理,2007,22(1):1-11. 被引量：82
5FERREIRA I, SPINELLI J E, PIRES J C, et al. The effect of melt temperature profile on the transient metal/mold heat transfer coefficient during solidification [J]. Materials Science and Engineering A, 2005, 408(1-2): 317-325.
6LEE J, KIM H S, WON C W, et al. Effect of the gap distance on the cooling behavior and the microstructure of indirect squeeze cast and gravity die cast 5083 wrought A1 alloy [J]. Materials Science and Engineering A, 2002, 338(1-2): 182-190.
7NARAYAN P K, RAVISHANKAR B. Effect of modification melt treatment on casting/chill interracial heat transfer and electrical conductivity of Al-13% Si alloy [J]. Materials Science and Engineering A, 2003, 360(1- 2): 293-298.
8LOULOU T, ARTYUKHIN E, BARDON J. Estimation of thermal contact resistance during the first stages of metal solidification process. II. Experimental setup and results [J]. International Journal of Heat and Mass Transfer, 1999, 42(12): 2129-2142.
9BOUCHARD D, LEBOEUF S, NADEAU J P, et al. Dynamic wetting and heat transfer at the initiation of alu- minum solidification on copper substrates [J].Journal of Materials Science, 2009, 44(8): 1923-1933.
10NOLLI P, CRAMB A. Interaction between iron droplets and H2S during solidification: Effects on heat trans- fer, surface tension and composition [J]. ISIJ International, 2007, 47(9): 1284-1293.

共引文献48

1程思飞,焦海涛,许云波.薄带连铸取向Fe-6.5%Si钢形变热处理过程组织演化[J].钢铁研究学报,2019,31(2):233-238. 被引量：1
2徐慧,李天生.回火温度对Nb微合金化NM500钢组织和性能的影响[J].金属热处理,2020,45(9):116-120. 被引量：9
3Hui-zhong LI,Yi-xuan CHE,Xiao-peng LIANG,Hui TAO,Qiang ZHANG,Fei-hu CHEN,Shuo HAN,Bin LIU.Microstructure and high-temperature mechanical properties of near net shaped Ti−45Al−7Nb−0.3W alloy by hot isostatic pressing process[J].Transactions of Nonferrous Metals Society of China,2020,30(11):3006-3015. 被引量：5
4周峰峦,王存宇,曹文全,董瀚.热轧逆相变退火中锰钢的疲劳性能[J].钢铁,2020,55(12):87-91. 被引量：5
5赵征志,陈伟健,高鹏飞,康涛,赵棪,唐荻.先进高强度汽车用钢研究进展及展望[J].钢铁研究学报,2020,32(12):1059-1076. 被引量：83
6刘思涵,王存宇,王昌,徐海峰,曹文全.Al对锻态中锰钢组织与性能的影响[J].钢铁研究学报,2020,32(12):1141-1147. 被引量：2
7曹晓琳,朱光明,乔松,岳博文,徐绵广.全因子试验方法在薄带连续铸轧中的应用[J].塑性工程学报,2021,28(3):103-109. 被引量：4
8S.J.Wu,Z.Q.Liu,R.T.Qu,Z.F.Zhang.Designing metallic glasses with optimal combinations of glass-forming ability and mechanical properties[J].Journal of Materials Science & Technology,2021(8):254-264.
9王文芳,潘红波,赵淮北,崔江涛,韩爱侠,汪杨.合金元素对热轧中锰钢组织及力学性能的影响[J].材料热处理学报,2021,42(4):81-86. 被引量：2
10侯晓英,孙卫华,曹光明,展英姿,金光宇,任东.一种TRIP型双相钢的显微组织形貌特征与强塑性机制[J].材料热处理学报,2021,42(5):104-110. 被引量：4

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2任三兵,杜锋,樊俊飞,张捷宇.薄带连铸布流器数学物理模拟研究[J].宝钢技术,2009,2(4):19-22. 被引量：2
3董建宏,王楠,陈敏,徐磊,黄伟军.双辊薄带铸轧熔池内流场和温度场数值模拟[J].过程工程学报,2014,14(2):211-216. 被引量：8
4文光华,祝明妹,王纪元,何俊范,丁培道.双辊薄带连铸熔池液面波动及流体混合特征模拟研究[J].钢铁研究,2001,29(6):21-26. 被引量：13
5徐益龙,孙济鹏,潘湾萍,张捷宇,王波.低碳钢薄带双辊连铸凝固过程的数值模拟[J].上海金属,2020,42(2):91-97. 被引量：8
6蒋恩,刘刚.双辊薄带连铸铸辊水冷系统数值模拟[J].一重技术,2020(1):1-4. 被引量：3
7王三众,黄兆猛,于辉,杜凤山.双辊铸轧布流系统优化及熔池流场规律研究[J].燕山大学学报,2021,45(5):387-393. 被引量：2
8朱光明,殷继丽,任青文,丁明凯,闵范磊,曹晓琳.基于有限元法的布流器水口结构优化研究[J].钢铁研究学报,2019,31(1):8-14. 被引量：5

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3Guang‑Hong Lu,Guang‑Nan Luo.Preface to the special issue on metallic materials for fusion applications[J].Tungsten,2020,2(1):1-2.
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10Siyu WANG,Lin ZHAN,Huifeng XI,O.T.BRUHNS,Heng XIAO.Unified simulation of hardening and softening effects for metals up to failure[J].Applied Mathematics and Mechanics(English Edition),2021,42(12):1685-1702. 被引量：1

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