Effect of annealing time on microstructure and properties of Fe-2.0Mn-4.7Al-0.4C low density high strength steel

doi:10.13251/j.issn.0254-6051.2024.11.016

Abstract

Abstract: Annealing temperature of Fe-2.0Mn-4.7Al-0.4C steel was determined to be 860 ℃ by using JMatPro simulation software. The effect of annealing time on the microstructure and mechanical properties of the hot-rolled Fe-2.0Mn-4.7Al-0.4C steel was studied by means of optical microscope, scanning electron microscope, and electronic universal material testing machine. The results show that after annealing treatment, the microstructure of the hot-rolled Fe-2.0Mn-4.7Al-0.4C steel transforms from δ ferrite, α ferrite, martensite, pearlite, and cementite to δ ferrite, pearlite, and retained austenite. When annealed for 120 min, the tensile fracture morphology of the specimen shows a transition from brittle fracture to ductile fracture. The tested steel has the best comprehensive mechanical properties with tensile strength of 515.6 MPa, yield strength of 361.0 MPa, maximum elongation of 35.4%, and strength-elongation product of 18.3 GPa·%. However, when the annealing time is too long to reach 180 min, the grain grows and aggregates, the dislocation movement disappears, resulting in a decrease in material toughness and an increase in material brittleness. The fracture surface is mainly composed of ductile dimples and relatively smooth cleavage surfaces.

Key words: low density steel, annealing time, fracture morphology, microstructure, mechanical properties

CLC Number:

TG142

Peng Xiachao, Tang En, Zhang Xiangyun. Effect of annealing time on microstructure and properties of Fe-2.0Mn-4.7Al-0.4C low density high strength steel[J]. Heat Treatment of Metals, 2024, 49(11): 112-117.

References

[1]张磊峰, 宋仁伯, 赵超, 等. 新型汽车用钢—低密度高强韧钢的研究进展[J]. 材料导报, 2014, 28(19): 111-118, 129.
Zhang Leifeng, Song Renbo, Zhao Chao, et al. Research progress of new automotive steel-low-density high strength toughness steel[J]. Materials Reports, 2014, 28(19): 111-118, 129.
[2]秦唯铭, 杜冰, 朱绍伟, 等. 环境温度对长玻纤增强聚丙烯单向拉伸力学性能的影响[J]. 材料导报, 2023, 37(20): 237-242.
Qin Weiming, Du Bing, Zhu Shaowei, et al. Effect of environment temperature on uniaxial tensile properties of long glass fiber reinforced polypropylene[J]. Materials Reports, 2023, 37(20): 237-242.
[3]李光瀛, 王利, 马鸣图, 等. 第3代先进高强度钢AHSS汽车板的开发[J]. 轧钢, 2019, 36(5): 1-13.
Li Guangying, Wang Li, Ma Mingtu, et al. Development of 3rd generation advanced high strength steel for automotive[J]. Steel Rolling, 2019, 36(5): 1-13.
[4]Bykov O, Sydorchuk O, Myroniuk L, et al. X-ray analysis of features of both crystalline structure of main phases formation and properties of 4Kh4N5M4F2 steel (RATE steel) at handling[J]. Metallofizika i Noveishie Tekhnologii, 2021, 43(11): 1523-1536.
[5]Kim H, Suh D, Kim J N. Fe-Al-Mn-C lightweight structural alloys: A review on the microstructures and mechanical properties[J]. Science and Technology of Advanced Materials, 2013, 14(1): 784-795.
[6]王英虎. 汽车用高强韧Fe-Mn-Al-C系低密度钢研究进展[J]. 铸造技术, 2019, 40(8): 868-873.
Wang Yinghu. Research progress of Fe-Mn-Al-C low density steel with high strength and toughness for automobile[J]. Foundry Technology, 2019, 40(8): 868-873.
[7]苏宏东, 樊伟, 冯运莉. 退火温度对冷轧Fe-0.4C-10Mn-6Al高强钢组织与力学性能的影响[J]. 金属热处理, 2022, 47(5): 126-131.
Su Hongdong, Fan Wei, Feng Yunli. Effect of annealing temperature on microstructure and mechanical properties of cold-rolled Fe-0.4C-10Mn-6Al high strength steel[J]. Heat Treatment of Metals, 2022, 47(5): 126-131.
[8]侯美伶, 李晨潇, 孔祥伟, 等. 热处理工艺对Fe-Mn-Al-C钢组织和性能的影响[J]. 特殊钢, 2023, 44(2): 96-100.
Hou Meiling, Li Chenxiao, Kong Xiangwei, et al. Effect of heat treatment process on microstructure and properties of Fe-Mn-Al-C steel[J]. Special Steel, 2023, 44(2): 96-100.
[9]Sheng Weiqin, Yu Liu, Qing Guohao. High carbon microalloyed martensitic steel with ultrahigh strength-ductility[J]. Materials Science and Engineering A, 2016, 663: 151-156.
[10]田苗, 陈婷婷, 马进, 等. 不同热处理工艺对ZG20SiMn钢奥氏体化后组织和力学性能的影响[J]. 热加工工艺, 2022, 51(10): 118-121.
Tian Miao, Chen Tingting, Ma Jin, et al. Effects of different heat treatment processes on microstructure and mechanical properties of ZG20SiMn steel after austenitization[J]. Hot Working Technology, 2022, 51(10): 118-121.
[11]杨旗, 王俊峰, 丛郁, 等. 轻质钢的研究进展(一)—富Al无间隙原子钢和铁素体轻质钢[J]. 宝钢技术, 2015, 8(3): 1-10.
Yang Qi, Wang Junfeng, Cong Yu, et al. State of knowledge on lightweight steels(Part Ⅰ)—Al-rich interstitial-free steels and ferritic lightweight steels[J]. Baosteel Technology, 2015, 8(3): 1-10.
[12]杨旗, 丛郁, 王俊峰, 等. 轻质钢的研究进展(二)—铁素体-奥氏体双相轻质钢和奥氏体轻质钢[J]. 宝钢技术, 2015, 8(4): 1-8.
Yang Qi, Cong Yu, Wang Junfeng, et al. State of knowledge on lightweight steels(Part Ⅱ)——Ferrite-austenite dual-phase lightweight steels and austenitic lightweight steels[J]. Baosteel Technology, 2015, 8(4): 1-8.
[13]Kim S H, Kim H, Kim N J. Brittle intermetallic compound makes ultrastrong low-density steel with large ductility[J]. Nature, 2015, 518: 77-79.
[14]Sen G. Low density Fe-Mn-Al-C steels phase structures mechanisms and properties[J]. ISU International, 2021, 61(1): 16-25.
[15]蔡梦茹, 段美琪, 洪志伟, 等. 氮含量对25Mn2CrVS贝氏体型非调质钢组织和性能的影响[J]. 金属热处理, 2020, 45(4): 34-39.
Cai Mengru, Duan Meiqi, Hong Zhiwei, et al. Effect of nitrogen content on microstructure and properties of 25Mn2CrVS bainite type non-quenched and tempered steel[J]. Heat Treatment of Metals, 2020, 45(4): 34-39.
[16]Zhi H C, Hua D, Zheng Y Y. Microstructural evolution and deformation behavior of a hot-rolled and heat treated Fe-8Mn-4Al-0.2C steel[J]. Journal of Materials Engineering and Performance, 2014, 23(4): 1171-1137.
[17]刘正东, 杨钢, 程世长, 等. 2.25Cr-1Mo钢回火过程中碳化物析出顺序的研究[J]. 金属热处理, 2005, 30(4): 32-34.
Liu Zhengdong, Yang Gang, Cheng Shichang, et al. Investigation of carbide precipitation order of 2.25Cr-1Mo steel during tempering[J]. Heat Treatment of Metals, 2005, 30(4): 32-34.
[18]Sohn S S, Lee B J, Lee S. Effect of annealing temperature on microstructural modification and tensile properties in 0.35C-3.5Mn-5.8Al lightweight steel[J]. Acta Materialia, 2013, 61(13): 5050-5066.
[19]Wang Y, Sun J, Jiang T, et al. A low-alloy high-carbon martensite steel with 2.6 GPa tensile strength and good ductility[J]. Acta Materialia, 2018, 158(158): 247-256.
[20]宋新莉, 彭宇凡, 李兆振, 等. 高强度无取向电工钢疲劳性能及断裂机制[J]. 电工钢, 2022, 4(1): 12-17.
Song Xinli, Peng Yufan, Li Zhaozhen, et al. Fatigue properties and fracture mechanism of high strength non-oriented electrical steel[J]. Electrical Steel, 2022, 4(1): 12-17.
[21]张开, 王学, 倪满生, 等. 高温时效对P91钢组织及硬度的影响[J]. 金属热处理, 2022, 47(12): 7-12.
Zhang Kai, Wang Xue, Ni Mansheng, et al. Effect of high temperature aging on microstructure and hardness of P91 steel[J]. Heat Treatment of Metals, 2022, 47(12): 7-12.