超细晶铁素体双峰结构及其对中碳钢力学性能的影响

doi:10.13251/j.issn.0254-6051.2023.05.009

金属热处理 ›› 2023, Vol. 48 ›› Issue (5): 54-59.DOI: 10.13251/j.issn.0254-6051.2023.05.009

超细晶铁素体双峰结构及其对中碳钢力学性能的影响

张家豪¹, 李红斌¹, 赵志浩¹, 徐海卫², 韩赟², 田亚强¹, 陈连生¹

1.华北理工大学冶金与能源学院, 河北唐山 063210;
2.首钢京唐钢铁联合有限责任公司技术中心, 河北唐山 063200

收稿日期:2022-11-15 修回日期:2023-03-20 出版日期:2023-05-25 发布日期:2023-06-21
通讯作者: 李红斌,副教授,博士,E-mail: lihongbinxp@126.com
作者简介:张家豪(1999—),男,硕士研究生,主要研究方向为材料加工新技术与组织性能控制,E-mail: 1612567427@qq.com。
基金资助:
河北省科技厅重点研发计划(20311004D);河北省自然科学基金高端钢铁冶金联合基金(E2020209124,E2020209127,E2020209040);河北省自然科学基金重点项目(E2022209049)

Effect of ultrafine grain ferrite bimodal structure on mechanical properties of medium carbon steel

Zhang Jiahao¹, Li Hongbin¹, Zhao Zhihao¹, Xu Haiwei², Han Yun², Tian Yaqiang¹, Chen Liansheng¹

1. College of Metallurgy and Energy, North China University of Science and Technology, Tangshan Hebei 063210, China;
2. Technology Center, Shougang Jingtang Iron and Steel United Co., Ltd., Tangshan Hebei 063200, China

Received:2022-11-15 Revised:2023-03-20 Online:2023-05-25 Published:2023-06-21

摘要/Abstract

摘要： 对含碳0.49%的中碳钢在两相区不同温度下淬火,随后冷轧50%并退火,制备中碳钢铁素体双峰结构。通过扫描电镜(SEM)、背散射电子衍射(EBSD)对双峰结构进行表征,并通过室温拉伸试验分析了双峰结构对力学性能的影响。结果表明,随两相区淬火温度的升高,铁素体平均晶粒尺寸减小;当淬火温度为770 ℃时,试验钢的强度最高,750 ℃时伸长率最高,760 ℃时强塑积最高。当亚微米晶比例为31.4%,粗细晶峰值晶粒尺寸为2.51和0.79 μm时,试验钢具有较好的强塑性匹配。

关键词: 超细晶铁素体, 中碳钢, 双峰结构, 力学性能, 强塑积

Abstract: A medium carbon steel with 0.49%C was quenched at different temperatures in two-phase zone, then cold rolled 50% and annealed to obtain the ferritic bimodal structure. The microstructure was characterized by means of scanning electron microscope (SEM) and electron backscattered diffraction(EBSD), and the effect of the bimodal structure on mechanical properties was analyzed by tensile experiments at room temperature. The results show that the average grain size of the ferrite decreases with the increase of the quenching temperature in the two-phase zone. The strength of the tested steel is the highest when quenched at 770 ℃, the elongation is the highest at 750 ℃, and the product of strength and elongation is the highest at 760 ℃. When the proportion of submicron grains is 31.4% and the peak grain sizes of coarse grains and fine grains are respectively 2.51 and 0.79 μm, the tested steel has better matching of strength and elongation.

Key words: ultrafine grain ferrite, medium carbon steel, bimodal structure, mechanical properties, product of strength and elongation

中图分类号:

TG156.1

张家豪, 李红斌, 赵志浩, 徐海卫, 韩赟, 田亚强, 陈连生. 超细晶铁素体双峰结构及其对中碳钢力学性能的影响[J]. 金属热处理, 2023, 48(5): 54-59.

Zhang Jiahao, Li Hongbin, Zhao Zhihao, Xu Haiwei, Han Yun, Tian Yaqiang, Chen Liansheng. Effect of ultrafine grain ferrite bimodal structure on mechanical properties of medium carbon steel[J]. Heat Treatment of Metals, 2023, 48(5): 54-59.

参考文献

[1]Sun B, Ma Y, Vanderesse N, et al. Macroscopic to nanoscopic in situ investigation on yielding mechanisms in ultrafine grained medium Mn steels: Role of the austenite-ferrite interface[J]. Acta Materialia, 2019, 178(7): 10-25.
[2]Filho I S, Sandim M, Ponge D, et al. Strain hardening mechanisms during cold rolling of a high-Mn steel: Interplay between submicron defects and microtexture[J]. Materials Science and Engineering A, 2019, 754(29): 636-649.
[3]Cui Y, Liu Z, Zhuang Z. Quantitative investigations on dislocation based discrete-continuous model of crystal plasticity at submicron scale[J]. International Journal of Plasticity, 2015, 69(2): 54-72.
[4]田亚强, 田耕, 郑小平, 等. 淬火配分贝氏体钢不同位置残余奥氏体C, Mn元素表征及其稳定性[J]. 金属学报, 2019, 55(3): 332-340.
Tian Yaqiang, Tian Geng, Zheng Xiaoping, et al. C and Mn elements characterization and stability of retained austenite in different locations of quenching and partitioning bainite steels[J]. Acta Metallurgica Sinica, 2019, 55(3): 332-340.
[5]Verma A K, Kumar A. Microstructure and mechanical properties of medium manganese steels[J]. Materials Today: Proceedings, 2022, 56(1): 356-367.
[6]Zha M, Zhang X H, Zhang H, et al. Achieving bimodal microstructure and enhanced tensile properties of Mg-9Al-1Zn alloy by tailoring deformation temperature during hard plate rolling (HPR)[J]. Journal of Alloys and Compounds, 2018, 765(4): 1228-1236.
[7]Zheng Y, Zeng W, Li D, et al. Fracture toughness of the bimodal size lamellar O phase microstructures in Ti-22Al-25Nb (at.%) orthorhombic alloy[J]. Journal of Alloys and Compounds, 2017, 709(3): 511-518.
[8]Wang Y, Chen M, Zhou F, et al. High tensile ductility in a nanostructured metal[J]. Nature, 2002, 419(10): 912-915.
[9]Park H W, Yanagimoto J. Formation process and mechanical properties of 0.2% carbon steel with bimodal microstructures subjected to heavy-reduction single-pass hot/warm compression[J]. Materials Science and Engineering A, 2013, 567(12): 29-37.
[10]Azizi-Alizamini H, Militzer M, Poole W J. A novel technique for developing bimodal grain size distributions in low carbon steels[J]. Scripta Materialia, 2007, 57(12): 1065-1068.
[11]Hosseini S M, Alishahi M, Najafizadeh A, et al. The improvement of ductility in nano/ultrafine grained low carbon steels via high temperature short time annealing[J]. Materials Letters, 2012, 74(1): 206-208.
[12]胡智评, 许云波, 刘慧, 等. 含δ铁素体Mn-Al系TRIP钢冷轧退火过程的组织性能[J]. 材料研究学报, 2018, 32(3): 177-183.
Hu Zhiping, Xu Yunbo, Liu Hui, et al. Microstructure and properties of TRIP steel with δ ferritic Mn-Al during cold rolling annealing[J]. Chinese Journal of Materials Research, 2018, 32(3): 177-183.
[13]Lee S W, Han G, Jun T S, et al. Effects of initial texture on deformation behavior during cold rolling and static recrystallization during subsequent annealing of AZ31 alloy[J]. Journal of Materials Science and Technology, 2021, 66(4): 139-149.
[14]肖洋洋, 詹华, 崔磊, 等. 1000 MPa级微合金化冷轧双相钢退火工艺及强韧化机制[J]. 钢铁研究学报, 2019, 31(10): 912-919.
Xiao Yangyang, Zhan Hua, Cui Lei, et al. An investigation on annealing process and strengthening and toughening mechanism of 1000 MPa grade microalloyed cold-rolled dual phase steel[J]. Journal of Iron and Steel Research, 2019, 31(10): 912-919.
[15]王卫卫, 刘浏, 李光灜. 高伸长率冷轧双相钢DP980显微组织及性能[J]. 钢铁研究学报, 2019, 31(12): 1053-1057.
Wang Weiwei, Liu Liu, Li Guangying. Microstructure and properties of high elongation cold rolled duplex DP980 steel[J]. Journal of Iron and Steel Research, 2019, 31(12): 1053-1057.
[16]Zhang R, Xu Z, Deng Y, et al. Characterizing the back stress of ultra-thin metallic sheet via pre-strain tension/bending process[J]. Journal of Materials Processing Technology, 2020, 279(5): 116560.
[17]Kim Y, Asghari-Rad P, Lee J, et al. Solid solution induced back-stress in multi-principal element alloys: Experiment and modeling[J]. Materials Science and Engineering A, 2022, 835(2): 142621.
[18]张家榕, 李艳芬, 王光全, 等. 热处理对一种双峰晶粒结构超低碳 9Cr-ODS 钢显微组织与力学性能的影响[J]. 金属学报, 2022, 58(5): 623-636.
Zhang Jiarong, Li Yanfen, Wang Guangquan, et al. Effect of heat treatment on microstructure and mechanical properties of an ultra-low carbon 9Cr-ODS steel with bimodal grain structure[J]. Acta Metallurgica Sinica, 2022, 58(5): 623-636.
[19]Liu W, Wei Y, Zhang F, et al. Tensile behavior of ferritic/austenitic iron with a bimodal structure: An atomistic study[J]. Materials Today Communications, 2022, 32: 103883.
[20]钟群鹏, 赵子华. 断口学[M]. 北京: 高等教育出版社, 2006.

超细晶铁素体双峰结构及其对中碳钢力学性能的影响

Effect of ultrafine grain ferrite bimodal structure on mechanical properties of medium carbon steel

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