Influence of Finishing Cooling Temperature and Holding Time on Nanometer-size Carbide of Nb-Ti Microalloyed Steel 被引量：3

Influence of Finishing Cooling Temperature and Holding Time on Nanometer-size Carbide of Nb-Ti Microalloyed Steel

导出

摘要 The nanometer-size carbides formed in ferrite matrix of Nb-Ti microalloyed steel at different finishing cooling temperatures and holding time have been investigated. The characteristics of nanometer-size carbides in ferrite were observed by transmission electron microscopy, and mechanical properties of ferrite were detected by a nano-hardness tester. The results showed that interphase precipitation and diffusion precipitation were observed at different finishing cooling temperatures, and the interphase precipitation was planar and curved. Sheet spacing of inter-phase precipitation increased with the increase of finishing cooling temperature and changed a little when holding for 50--1000 s. Interphase precipitation shows higher nano-hardness at 640℃ compared with diffusion precipitation at 600℃, and the contribution of interphase precipitation to the mechanical properties of ferrite was larger than that of diffusion precipitation. The nanometer-size carbides formed in ferrite matrix of Nb-Ti microalloyed steel at different finishing cooling temperatures and holding time have been investigated. The characteristics of nanometer-size carbides in ferrite were observed by transmission electron microscopy, and mechanical properties of ferrite were detected by a nano-hardness tester. The results showed that interphase precipitation and diffusion precipitation were observed at different finishing cooling temperatures, and the interphase precipitation was planar and curved. Sheet spacing of inter-phase precipitation increased with the increase of finishing cooling temperature and changed a little when holding for 50--1000 s. Interphase precipitation shows higher nano-hardness at 640℃ compared with diffusion precipitation at 600℃, and the contribution of interphase precipitation to the mechanical properties of ferrite was larger than that of diffusion precipitation.

作者 Hai-long YI Yang XU Ming-xue SUN Zhen-yu LIU Guo-dong WANG

机构地区 State Key Laboratory of Rolling and Automation

出处《Journal of Iron and Steel Research International》 SCIE EI CAS CSCD 2014年第4期433-438,共6页

基金 Item Sponsored by National Natural Science Foundation of China(51104046) Fundamental Research Funds for Central Universities of China(N120407001,N120807001)

关键词 nanometer-size arbide Nb-Ti microalloyed steel interphase precipitation diffusion precipitation nanometer-size arbide Nb-Ti microalloyed steel interphase precipitation diffusion precipitation

分类号 TG135.5 [一般工业技术—材料科学与工程]

引文网络
相关文献

参考文献14

1S.S. Campos, E.V. Morales, H.J. Kestenbach, Metall. Ma ter. Trans. A 32 (2001) 1245 1248.
2R. D. K. Misra, K.K. Tenneti, G.C. Weatherly, Metall. Mater. Trans. A 34 (2003) 2341-2351.
3R. Okamoto, A. Borgenstam, J. Agren, Acta Mater 4783 4790. 58 (2010).
4W. Y. Hung, P. Y. Chen, C. Y. Huang, J. R. Yang, Acta Ma- ter. 59 (2011) 6264 6274.
5C.Y. Chen, H.W. Yen, F. H. Kao, W.C. Li, C.Y. Huang, J. R. Yang, S. H. Wang, Mater. Sci. Eng. A 499 (2009) 162-166.
6H.W. Yen, C.Y. Huang, J.R. Yang, Scripta Mater. 61 (2009) 616 619.
7Y. Funakawa, T. Shiozaki, K. Tomita, T. Yamamoto, E. Maeda, ISIJ Int. 44 (2004) 1945-1951.
8R. M. Smith, D. P. Dunne, Mater. Forum 11 (1988) 166 181.
9R. W. K. Honeycombe, Metall. Trans. A 7 (1976) 915-936.
10A. D. Batte, R.W. Honeycom, J. Iron Steel Inst. 211 (1973) 284-299.

同被引文献52

1衣海龙,龙雷周,刘振宇,王国栋.Ti-Mo微合金钢铁素体中的析出物[J].材料热处理学报,2015,36(3):56-61. 被引量：9
2徐曼,孙新军,刘清友,董瀚,雍岐龙,黄金亮.低碳含钒钢组织变化及V(C,N)析出规律[J].钢铁钒钛,2005,26(2):25-30. 被引量：23
3刘文庆,朱晓勇,王晓姣,钟柳明,周邦新.铌钒微合金钢中碳化物的析出过程[J].材料科学与工艺,2010,18(2):164-167. 被引量：7
4傅杰,李光强,于月光,毛新平,方克明.基于纳米铁碳析出物的钢综合强化机理[J].中国工程科学,2011,13(1):31-42. 被引量：17
5段修刚,蔡庆伍,武会宾.Ti-Mo全铁素体基微合金高强钢纳米尺度析出相[J].金属学报,2011,47(2):251-256. 被引量：38
6Pasi P.Suikkanen,Cyril Cayron,Anthony J.DeArdo,L.Pentti Karjalainen.Crystallographic Analysis of Martensite in 0.2C-2.0Mn-1.5Si-0.6Cr Steel using EBSD[J].Journal of Materials Science & Technology,2011,27(10):920-930. 被引量：8
7焦增宝,刘锦川.新型纳米强化超高强度钢的研究与进展[J].中国材料进展,2011,30(12):6-11. 被引量：33
8赵显蒙,康永林,韩启航.1000MPa级冷轧双相钢奥氏体的等温相变动力学[J].材料热处理学报,2013,34(1):53-59. 被引量：6
9刘爽,唐广波,李激光,李斌,高韩锋.超高强度钢中复合MC型颗粒的沉淀析出及强化机制[J].钢铁,2014,49(3):68-73. 被引量：6
10陈俊,吕梦阳,唐帅,刘振宇,王国栋.V-Ti微合金钢的组织性能及相间析出行为[J].金属学报,2014,50(5):524-530. 被引量：35

引证文献3

1Sayed Ghafar Hashemi,B.Eghbali.Analysis of the formation conditions and characteristics of interphase and random vanadium precipitation in a low-carbon steel during isothermal heat treatment[J].International Journal of Minerals,Metallurgy and Materials,2018,25(3):339-349. 被引量：5
2杨洪波,王豪,赵旭,亓伟伟,刘洪银,孙建卫.微合金高强钢纳米相间析出行为研究进展[J].钢铁,2021,56(12):10-21. 被引量：14
3侯晓英,刘万春,王军,丁明凯,初林,王业勤.超高强复相钢组织调控及强塑性提升机理[J].中国冶金,2024,34(1):61-71. 被引量：1

二级引证文献20

1Zhen-jia Xie,Cheng-jia Shang,Xue-lin Wang,Xue-min Wang,Gang Han,Raja-devesh-kumar Misra.Recent progress in third-generation low alloy steels developed under M^3 microstructure control[J].International Journal of Minerals,Metallurgy and Materials,2020,27(1):1-9. 被引量：8
2Fan Zeng,Xue-jiao Bai,Cheng-liang Hu,Min-jun Tang,Zhen Zhao.Effect of plastic strain and forming temperature on magnetic properties of low-carbon steel[J].International Journal of Minerals,Metallurgy and Materials,2020,27(2):210-219. 被引量：1
3宋扬,刘丽华,张中武.钛微合金化低碳钢的研究进展[J].材料导报,2021,35(15):15175-15182. 被引量：13
4杨洪波,王豪,赵旭,亓伟伟,刘洪银,孙建卫.微合金高强钢纳米相间析出行为研究进展[J].钢铁,2021,56(12):10-21. 被引量：14
5沈国慧,胡斌,杨占兵,罗海文.回火温度对含δ铁素体高铝中锰钢力学性能和显微组织的影响[J].金属学报,2022,58(2):165-174. 被引量：5
6安璐,王雯雯,陈波涛,杨俊,邢立东,王敏.中碳含硫结构钢中MnS的析出行为研究[J].金属材料与冶金工程,2022(2):31-35. 被引量：1
7张琪,王厚昕,朱敏,苏雪,周明星,徐光.Nb微合金化高碳钢奥氏体晶粒长大原位观察[J].钢铁研究学报,2022,34(8):840-847. 被引量：10
8邹英,刘华赛,韩赟,滕华湘,蒋光锐.汽车用热基镀锌高强钢的研发进展[J].钢铁,2022,57(12):118-130. 被引量：11
9孟静,常帅,陈嘉宇,关建辉.热轧含Ti微合金钢拉伸性能及冲击韧性的改善[J].中国冶金,2023,33(2):106-113. 被引量：4
10蒋波,冯奕洁,王芝林,王海龙,苗红生,刘雅政.汽车用铁素体-珠光体型非调质钢研究现状[J].钢铁,2023,58(3):11-24. 被引量：7

1You-rong Xu,Zhi-yong Wang.Recrystallization and Precipitation Behavior during the Hot Deformation of Nb-Ti Microalloyed Steels[J].Advances in Manufacturing,2000(1):81-86.
2ZHANG Li,ZHAO Su.Influence of cooling rates on the precipitation behavior and microstructure of Nb-Ti microalloyed steel[J].Baosteel Technical Research,2012,6(3):8-12.
3YUAN Xiangqian JIAO Sihai.Effect of Ti content on the yield strength of Nb-Ti microalloyed steels[J].Baosteel Technical Research,2009,3(4):53-55. 被引量：1
4赵素,吴玉娟,何美凤,张立.Effects of Cooling Rates on Microstructures and Mechanical Properties of Nb-Ti Microalloyed Steel[J].Journal of Shanghai Jiaotong university(Science),2012,17(6):653-657. 被引量：3
5B.Eghbali,A.Abdollah-zadeh.Effect of Strain Rate on the Ferrite Grain Refinement in a Low Carbon Nb-Ti Microalloyed Steel during Low Temperature Deformation[J].Journal of Materials Science & Technology,2005,21(6):851-855. 被引量：4
6Wen-Zhen Xia,Xian-Ming Zhao,Xiao-Ming Zhang,Di Wu.Effects of Quenching Process on Microstructure and Mechanical Properties of Low Carbon Nb-Ti Microalloyed Steel[J].Journal of Harbin Institute of Technology(New Series),2013,20(4):73-77. 被引量：2
7B Eghbali.Effect of Hot Torsion Parameters on Development of Ultrafine Ferrite Grains in Microalloyed Steel[J].Journal of Iron and Steel Research International,2012,19(1):47-52.
8Wenjin Nie, Shanwu Yang, Shaoqiang Yuan, and Xinlai HeMaterials Science and Engineering School, University of Science and Technology Beijing, Beijing 100083, China.Dissolving of Nb and Ti carbonitride precipitates in microalloyed steels[J].Journal of University of Science and Technology Beijing,2003,10(5):78-80. 被引量：8
9周兴灵,彭卫珍,周书助.硬质合金用成型剂现状和发展的探讨[J].湖南冶金职业技术学院学报,2008,8(4):108-111. 被引量：8
10韩美.氢的纯化方法(Union Carbide法)[J].低温与特气,1986,4(1):73-74.

Journal of Iron and Steel Research International

2014年第4期

浏览历史

内容加载中请稍等...

Influence of Finishing Cooling Temperature and Holding Time on Nanometer-size Carbide of Nb-Ti Microalloyed Steel 被引量：3

参考文献14

同被引文献52

引证文献3

二级引证文献20

相关作者

相关机构

相关主题

浏览历史