23MnNiMoCr54钢的热变形行为

doi:10.13251/j.issn.0254-6051.2021.05.020

摘要/Abstract

摘要： 利用DIL 805A型热膨胀仪测定了23MnNiMoCr54钢的热膨胀曲线,结合硬度检验绘制出试验钢的CCT曲线,并对其动态相变及动态再结晶规律进行了研究分析。结果表明,23MnNiMoCr54钢的临界转变点Ac₃=806 ℃,Ac₁=713 ℃,CCT曲线中无珠光体转变区,当冷速≥0.5 ℃/s时,开始发生马氏体相变。变形量为10%时,变形温度在850~1150 ℃范围内时,试验钢的奥氏体晶粒边界稳定,晶粒大小没有发生明显变化,没有发生动态再结晶,软化机制以动态回复为主。变形量为40%时,变形温度在850 ℃时试验钢没有发生动态再结晶,软化机制以回复为主;温度为900~950 ℃时出现了不稳定的奥氏体晶界和细小晶粒,动态再结晶开始发生;温度为1000 ℃时,发生了完全动态再结晶。变形量为50%时,变形温度在850~950 ℃时试验钢出现了不稳定的奥氏体晶界和细小晶粒,发生了部分再结晶;温度为1000 ℃时,发生了完全动态再结晶。变形量为60%时,变形温度在850~950 ℃时试验钢出现了不稳定的奥氏体晶界和细小晶粒,发生了部分再结晶;温度为1000 ℃时,发生了完全动态再结晶。

关键词: 23MnNiMoCr54钢, 膨胀仪法, CCT曲线, 再结晶, 晶粒度

Abstract: Thermo dilatometric curve of 23MnNiMoCr54 steel was measured by a DIL 805A thermal dilatometer, CCT curve of the tested steel was drawn in combination with the hardness test, and the dynamic phase transformation and dynamic recrystallization laws were studied and analyzed. The results show that the critical transformation temperatures of the 23MnNiMoCr54 steel are: Ac₃=806 ℃, Ac₁=713 ℃, and there is no pearlite transformation zone in the CCT curve. When the cooling rate is greater than or equal to 0.5 ℃/s, the martensitic transformation begins. When the deformation amount is 10% and deformed at 850-1150 ℃, the austenite grain boundary of the tested steel is stable, the grain size does not change significantly, no dynamic recrystallization occurs, and the softening mechanism is mainly dynamic recovery. When the deformation amount is 40%, no dynamic recrystallization of the tested steel occurs at 850 ℃, and the softening mechanism is mainly recovery. Unstable austenite grain boundaries and fine grains appear when the deformation temperature is at 900-950 ℃, and dynamic recrystallization begins to occur. At 1000 ℃, complete dynamic recrystallization occurs. When the deformation amount is 50%, unstable austenite grain boundaries and fine grains appear when deformed at 850-950 ℃, and partial recrystallization occurs. At deformation temperature of 1000 ℃, complete dynamic recrystallization occurs. When the deformation amount is 60%, unstable austenite grain boundaries and fine grains of the tested steel appear when deformed at 850-950 ℃, and partial recrystallization occurs. At deformation temperature of 1000 ℃, complete dynamic recrystallization occurs.

Key words: 23MnNiMoCr54 steel, dilatometer method, CCT curve, recrystallization, grain size

中图分类号:

TG115.21

李硕, 方光锦, 汪青芳, 陈世昌, 卢春光. 23MnNiMoCr54钢的热变形行为[J]. 金属热处理, 2021, 46(5): 127-131.

Li Shuo, Fang Guangjin, Wang Qingfang, Chen Shichang, Lu Chunguang. Hot deformation behavior of 23MnNiMoCr54 steel[J]. Heat Treatment of Metals, 2021, 46(5): 127-131.

参考文献

[1]王运玲, 冯桂萍. 高级链条钢23MnNiMoCr54质量研究[J]. 热加工工艺, 2010, 39(8): 68-70.
Wang Yunling, Feng Guiping. Study on quality of advanced chain steel 23MnNiMoCr54[J]. Hot Working Technology, 2010, 39(8): 68-70.
[2]邵淑艳, 孟羽, 廖书全. 高强度链条钢23MnNiMoCr54质量工艺研究[J]. 甘肃冶金, 2010, 32(6): 15-18.
Shao Shuyan, Meng Yu, Liao Shuquan. Study on quality and technology of 23MnNiMoCr54 for high strength chain steel[J]. Gansu Metallurgy, 2010, 32(6): 15-18.
[3]张剑锋. 高强度矿用链条23MnNiMoCr54的生产[J]. 江苏冶金, 2006(2): 25-26.
Zhang Jianfeng. Production of high-strength mining chain 23MnNiMoCr54[J]. Jiangsu Metallurgy, 2006(2): 25-26.
[4]杨勇, 郭红英, 段丙谦, 等. 23MnNiMoCr54链环钢断裂原因分析[J]. 物理测试, 2013, 31(1): 41-46.
Yang Yong, Guo Hongying, Duan Bingqian, et al. Fracture reason of 23MnNiMoCr54 chains annulus[J]. Physics Examination and Testing, 2013, 31(1): 41-46.
[5]孙跃军, 李擎宇, 孙雷. 23MnNiMoCr54钢中温回火冲击功的理论计算[J]. 兵器材料科学与工程, 2013, 36(3): 45-48.
Sun Yuejun, Li Qingyu, Sun Lei. Impact energy calculation of medium temperature tempered 23MnCrNiMo54 steel[J]. Ordnance Material Science and Engineering, 2013, 36(3): 45-48.
[6]曾海霞, 杨佳, 鲍雪君. 高强度矿用链条钢CCT曲线的测定与分析[J]. 机械工程师, 2013(10): 46-48.
Zeng Haixia, Yang Jia, Bao Xuejun. Measurement and analysis of CCT curve of high-strength mining chain steel[J]. Mechanical Engineer, 2013(10): 46-48.
[7]刘宗昌, 赵莉萍, 闫俊萍, 等. 23MnNiCrMo煤机链条钢的球化退火[J]. 特殊钢, 2001(1): 45-47.
Liu Zongchang, Zhao Liping, Yan Junping, et al. Spheroidizing annealing of chain steel 23MnNiCrMo for coal machine[J]. Special Steel, 2001(1): 45-47.
[8]万荣春, 于淼. 铌对低碳钢奥氏体的变形及动态回复再结晶的影响[J]. 热加工工艺, 2015, 44(2): 115-117, 120.
Wan Rongchun, Yu Miao. Effects of Nb on austenite dynamic recovery and dynamic recrystallization of low-carbon steels[J]. Hot Working Technology, 2015, 44(2): 115-117, 120.
[9]马越, 刘建生. 30Cr2Ni4MoV钢动态再结晶及微观组织演变研究[J]. 锻压技术, 2016, 41(3): 129-133.
Ma Yue, Liu Jiansheng. Research on dynamic recrystallization behavior and microstructure evolution of steel 30Cr2Ni4MoV[J]. Forging Stamping Technology, 2016, 41(3): 129-133.
[10]夏玉峰, 赵磊, 余春堂, 等. 42CrMo钢动态再结晶的临界条件[J]. 材料热处理学报, 2013, 34(4): 74-79.
Xia Yufeng, Zhao Lei, Yu Chuntang, et al. Dynamic recrystallization critical conditions of 42CrMo steel[J]. Transactions of Materials and Heat Treatment, 2013, 34(4): 74-79.
[11]方光锦. 系泊链用R4(22MnCrNiMo)钢CCT曲线测定及分析[J]. 金属热处理, 2020, 45(3): 208-211.
Fang Guangjin. Determination and analysis of CCT curves of R4 (22MnCrNiMo) steel for mooring chain[J]. Heat Treatment of Metals, 2020, 45(3): 208-211.

[1]	连轶博, 杨春雷, 王国栋, 宋威. 固溶处理对GH4080A高温合金微观组织的影响[J]. 金属热处理, 2022, 47(4): 46-52.
[2]	陈连生, 张露友, 田亚强, 杨子旋, 李红斌, 潘红波, 魏英立. 低碳高强舰船用钢的CCT曲线及其组织性能[J]. 金属热处理, 2022, 47(4): 63-68.
[3]	王国迪, 景然, 张曼雪, 冯甜, 余国庆, 解念锁. 冷轧变形量及再结晶对TC4合金组织与性能的影响[J]. 金属热处理, 2022, 47(3): 48-52.
[4]	王方军, 刘应龙, 时瑶, 万红, 刘斌斌. 等温退火处理对Inconel 625合金箔材组织和性能的影响[J]. 金属热处理, 2022, 47(3): 77-81.
[5]	郭亚洲, 宋宁宏, 倪雷, 凌华, 毕文珍, 韦习成. B1800HS热成形钢组织转变的JMatPro计算和试验研究[J]. 金属热处理, 2022, 47(3): 239-244.
[6]	张世进, 李凯, 易丹青, 刘会群. 冷轧TA5钛合金退火过程的再结晶行为及织构演变[J]. 金属热处理, 2022, 47(2): 1-8.
[7]	郝天赐, 吴雍壕, 阴树标, 曹建春, 罗瀚宇. Zr对Ti-Mo复合微合金化钢形变奥氏体静态再结晶动力学和析出相的影响[J]. 金属热处理, 2022, 47(2): 41-47.
[8]	李永顺, 玄伟东, 段方苗, 赵玉娟, 李俊杰, 王保军, 任兴孚, 任忠鸣. 应力对单晶高温合金再结晶的影响[J]. 金属热处理, 2022, 47(2): 48-52.
[9]	舒玮, 宋丽强, 张威. 热变形对含铌奥氏体不锈钢07Cr18Ni11Nb再结晶行为的影响[J]. 金属热处理, 2022, 47(2): 59-64.
[10]	冯运动, 邹宇明, 丁桦. Ti含量对IF钢再结晶温度及力学性能的影响[J]. 金属热处理, 2022, 47(2): 70-73.
[11]	陈建文, 袁伍丰, 蒋亦舟, 张晨, 易华清, 高毅强. 锻造加热温度对20Cr2Ni4A钢奥氏体晶粒长大及力学性能的影响[J]. 金属热处理, 2022, 47(2): 112-118.
[12]	马启林, 刘刚, 郑健, 阴树标, 李拔, 刘清友. Nb-V复合微合金化高钢级管线钢的奥氏体连续冷却转变[J]. 金属热处理, 2022, 47(1): 13-18.
[13]	张涛, 郑文杰, 李才巨. 冷拔后退火对Monel 400合金丝材的再结晶过程及力学性能的影响[J]. 金属热处理, 2022, 47(1): 56-62.
[14]	范合合, 金自力, 任慧平, 游兴华. 高Nb-Ti新能源汽车用无取向硅钢热轧过程的再结晶行为[J]. 金属热处理, 2022, 47(1): 88-93.
[15]	朱赫男, 陈刚, 杨佳伟, 张志建. Ti微合金化对22MnB5热成形钢组织和性能的影响[J]. 金属热处理, 2022, 47(1): 125-129.