Effect of tempering time on mechanical properties and microstructure of A-100 steel

doi:10.13251/j.issn.0254-6051.2021.02.024

Abstract

Abstract: Effect of tempering time on microstructure and mechanical properties of A-100 ultra-high strength steel after quenching+cryotreatment was studied by means of mechanical properties test, microstructure observation and fracture failure analysis. The results show that, when the A-100 steel tempered at 482 ℃, the reversed austenite is precipitated at the grain boundary of lath martensite, and M₂C-type carbide is precipitated around martensite. With the increase of tempering time, the amount of reversed austenite increases and disperses more uniformly, and the grain size of the martensite increases. With the increase of tempering time from 5 h to 8 h, the proof strength, plastic extension decreases from 1890 MPa to 1728 MPa; the tensile strength decreases from 2045 MPa to 1988 MPa, decreasing by about 8.57% and 2.78% respectively. However, the fracture toughness increases from 98.75 MPa·m^1/2 to 114.3 MPa·m^1/2, increasing by about 15.74%. When increasing tempering time, the dimple area of impact fracture decreases, and the average dimple area accounts for roughly is 86.2% of the total area after tempering for 5 h, while decreasing by about 70.1% when tempering for 8 h.

Key words: A-100 steel, tempering time, fracture toughness, retained austenite

CLC Number:

TG142.1

Hu Shengshuang, Shi Lili, He Kun, Zhao Gang, Wang Qing, Wang Wenbo, Wang Yaxing. Effect of tempering time on mechanical properties and microstructure of A-100 steel[J]. Heat Treatment of Metals, 2021, 46(2): 140-143.

References

[1] 李志,古立新,李惠曲,等.23Co14Ni12Cr3MoE(A-100)钢的研究进展[J].航空材料学报,2017,37(6):16-24.
Li Zhi,Gu Lixin,Li Huiqu,et al.Topics on applied basic theory research of 23Co14Ni12Cr3MoE(A-100) steel[J].Journal of Aeronautical Materials,2017,37(6):16-24.
[2] 贺亚勇,赵勇.起落架用A-100钢热处理力学性能质量控制研究[J].新技术新工艺,2016(6):79-82.
He Yayong,Zhao Yong.Research on quality control of the aircraft landing gear A-100 heat treatment[J].New Technology and New Process,2016(6):79-82.
[3] 秦玉荣,苏杰,杨卓越,等.三种超高强度钢的动态力学性能[J].金属热处理,2014,39(12):83-85.
Qin Yurong,Su Jie,Yang Zhuoyue,et al.Dynamic mechanical properties of three kinds of ultrahigh strength steel[J].Heat Treatment of Metals,2014,39(12):83-85.
[4] 王六定.超高强度钢A100力学性能及连续转变理论的研究[D].西安:西北工业大学,2000.
[5] Hyuck MoLee,Antony J Garratt-Reed,Samuel M Allen.Composition of M₂C phase in tempering of high Co-Ni steels[J].Scripta Metallurgica et Materialia,1991,25(3):685-688.
[6] Ayer R,Machmeier P M.Transmission electron microscopy examination of hardening and toughening phenomena in Aermet 100[J].Metallurgical Transactions A,1993,24:1943-1955.
[7] 张淑玉,王春旭,史庆南.跳过深冷处理对A100钢断裂韧性的影响[J].特钢技术,2006,12(4):8-9.
Zhang Shuyu,Wang Chunxu,Shi Qingnan.Effect of DF-skipped treatment on fracture toughness of A100 alloy[J].Special Steel Technology,2006,12(4):8-9.
[8] 冉刚,张建国,王泓,等.拉伸超载对超高强度钢A-100冲击疲劳性能的影响[J].热加工工艺,2012,41(14):94-101.
Ran Gang,Zhang Jianguo,Wang Hong,et al.Effect of tensile overloading on impact fatigue properties of ultra-high strength steel A-100[J].Hot Working Technology,2012,41(14):94-101.
[9] 汤智慧,刘鹏,王旭东,等.A100钢镀Cr防护技术在海洋环境下的腐蚀行为研究[J].材料工程,2011(9):50-55.
Tang Zhihui,Liu Peng,Wang Xudong,et al.Corrosion behaviour of chromium plating on A100 steel in marine environment[J].Journal of Materials Engineering,2011(9):50-55.
[10] 赵艳丽,王强,杨庆祥,等.喷丸工艺参数对A-100高强度钢残余应力场的影响[J].金属热处理,2013,38(8):10-14.
Zhao Yanli,Wang Qiang,Yang Qingxiang,et al.Effect of shot peening parameters on residual stress fields of A-100 high strength steel[J].Heat Treatment of Metals,2013,38(8):10-14.

[1]	Qi Xiaoliang, Li Yan, Ding Wei, Zhao Zengwu. Effect of original microstructure of medium manganese TRIP steel containing Al on microstructure and mechanical properties after intercritical annealing [J]. Heat Treatment of Metals, 2022, 47(4): 24-29.
[2]	Chen Liansheng, Fang Ning, Cao Zhongqian, Yang Zixuan, Li Hongbin, Pan Hongbo, Tian Yaqiang. Effect of intercritical warm-rolling reduction ratio on microstructure and properties of medium manganese steel treated by quenching and partitioning [J]. Heat Treatment of Metals, 2022, 47(3): 28-33.
[3]	Liu Tao, Wu Hongyan, Gao Xiuhua, Qin Dongyang, Du Linxiu. Effect of intercritical tempering temperature on microstructure and mechanical properties of Fe-4Mn-1.2Cr-0.3Cu-0.6Ni medium manganese steel [J]. Heat Treatment of Metals, 2022, 47(2): 91-98.
[4]	Dong Rui, Chen Lin, Cen Yaodong, Bao Xirong. Microstructure and fatigue crack growth of a bainitic steel under different heat treatments [J]. Heat Treatment of Metals, 2022, 47(2): 153-158.
[5]	Hou Yaqing, Zhang Yu, Yu Mingguang, Wang Jingjing, Yang Li, Su Hang. Thermodynamic calculation of retained austenite content in Q&P steel [J]. Heat Treatment of Metals, 2022, 47(1): 25-31.
[6]	Gao Yaping, Shi Zhongran, Jia Juan, Luo Xiaobing, Song Xinli. Effect of heat treatment process on microstructure and abrasive wear properties of dredging engineering ship steel [J]. Heat Treatment of Metals, 2022, 47(1): 32-37.
[7]	Qiu Xuyangfan, Yang Zhuoyue, Ding Yali. Solid solution treatment for improving cryogenic temperature toughness of Cr-Ni-Mo-Ti maraging stainless steel [J]. Heat Treatment of Metals, 2022, 47(1): 44-48.
[8]	Lu Chunxiang, Lin Tianzi, Cao Jianchun, Gao Peng, Zhan Fang, Liu Xing. Effect of tempering time on mechanical properties and microstructure of high strength anti-seismic fire-resistant steel plate [J]. Heat Treatment of Metals, 2022, 47(1): 156-162.
[9]	Deng Biao, Chen Peng, Wang Guodong. Effect of tempering temperature on microstructure and properties of secondary hardening martensitic stainless steel [J]. Heat Treatment of Metals, 2021, 46(9): 65-71.
[10]	Zhao Shaofu, Xu Hongxiang, Wang Hongwei, Guo Jingqiang, Li Ziyan, Chen Yan. Experimental study on improving carburizing and quenching hardness of gear made of 20Cr2Ni4A steel [J]. Heat Treatment of Metals, 2021, 46(7): 120-125.
[11]	Wang Lingqi, He Yanlin, Pan Le. Effect of tempering temperature on microstructure and mechanical properties of high nitrogen stainless bearing steel [J]. Heat Treatment of Metals, 2021, 46(6): 8-13.
[12]	Li Xiong, Lin Faju, Du Simin, Wu Chengchuan. Comparative analysis of high performance bearing steels [J]. Heat Treatment of Metals, 2021, 46(6): 14-20.
[13]	An Min, Fu Zhongyuan, Yuan Chao, Xia Yunzhi. Effects of post-quenching cleaning and cold treatment process on retained austenite content of 9Cr18 steel bearing ring [J]. Heat Treatment of Metals, 2021, 46(6): 21-23.
[14]	Qiu Xuyangfan, Yang Zhuoyue, Ding Yali. Effect of retained/reversed austenite on improving -196 ℃ cryogenic impact property of high strength stainless steel [J]. Heat Treatment of Metals, 2021, 46(5): 71-74.
[15]	Liang Jingyu, Shi Zengmin, Xie Hao, Deng Lichengui, Li Guangyu, Dai Lei. Alloying mode and microstructure control of ultra-high strength steels for automobile [J]. Heat Treatment of Metals, 2021, 46(4): 20-25.