Mo对耐热轴承钢高温长时力学性能及组织演变的影响

doi:10.13251/j.issn.0254-6051.2025.05.009

金属热处理 ›› 2025, Vol. 50 ›› Issue (5): 51-56.DOI: 10.13251/j.issn.0254-6051.2025.05.009

Mo对耐热轴承钢高温长时力学性能及组织演变的影响

郭春成¹, 李海宏², 曾西军², 周锴², 信振飞³, 迟宏宵¹, 马党参¹

1.钢铁研究总院有限公司特殊钢研究院, 北京 100081;
2.中国航发哈尔滨东安发动机有限公司, 黑龙江哈尔滨 150066;
3.抚顺特殊钢股份有限公司, 辽宁抚顺 113000

收稿日期:2024-12-08 修回日期:2025-03-17 发布日期:2025-06-25
通讯作者: 迟宏宵,正高级工程师,博士,E-mail:chihongxiao@163.com
作者简介:郭春成(1997—),男,博士研究生,主要研究方向为高温耐热轴承钢,E-mail:1842703512@qq.com。
基金资助:
国家科技重大专项(J2019-VI-0019-0134)

Effect of Mo on high-temperature long-term mechanical properties and microstructure evolution of a heat-resistant bearing steel

Guo Chuncheng¹, Li Haihong², Zeng Xijun², Zhou Kai², Xin Zhenfei³, Chi Hongxiao¹, Ma Dangshen¹

1. Research Institute of Special Steels, Central Iron and Steel Research Institute Co., Ltd., Beijing 100081, China;
2. China Aerospace Harbin Dong'an Engine Co., Ltd., Harbin Heilongjiang 150066, China;
3. Fushun Special Steel Co., Ltd., Fushun Liaoning 113000, China

Received:2024-12-08 Revised:2025-03-17 Published:2025-06-25

摘要/Abstract

摘要： 利用万能材料试验机、洛氏硬度计和扫描电镜,研究了添加4.6%Mo对耐热轴承钢高温(500 ℃)长时力学性能及组织演变的影响。结果表明:4.6%Mo的加入改善了未添加Mo轴承钢在500 ℃长时回火过程中抗拉强度和硬度下降的趋势,4.6Mo钢经回火处理100 h后,抗拉强度呈上升趋势,屈服强度在回火80 h时开始下降,硬度呈上升趋势;在整个回火过程中,0Mo钢的断面收缩率整体呈先下降后上升趋势,在回火80 h时达到最小值43.60%;4.6Mo钢的断面收缩率在回火0~50 h范围内没有明显变化,之后出现下降,在回火0 h时达到最大值62.16%,在回火80 h时达到最小值51.84%。随着回火时间的延长,0Mo试验钢中Fe₃C相数量减少,尺寸减小,而M₂₃C₆相尺寸变大,由回火10 h的25~42 nm长大至回火100 h的167~333 nm。随着回火时间延长,4.6Mo试验钢中M₂C相尺寸无明显变化,数量增多,M₂₃C₆相数量变化不明显,尺寸有所增大。Mo添加对碳化物的形核和长大机制影响较大,可使试验钢的回火稳定性提高。

关键词: 耐热轴承钢, 高温长时力学性能, 组织演变, 热稳定性

Abstract: Effect of addition of 4.6%Mo on high-temperature (500 ℃) long-term mechanical properties and microstructure evolution of a heat-resistant bearing steel was studied by means of universal material testing machine, Rockwell hardness tester and scanning electron microscope. The results show that the addition of 4.6%Mo improves the decreasing trend of tensile strength and hardness of the tested bearing steel without Mo addition under 500 ℃ long-term tempering. After tempering for 100 h, the tensile strength and the hardness of 4.6Mo steel show an upward trend, and the yield strength begins to decrease when the tempering time is 80 h. During the entire tempering process, the percentage reduction of area of 0Mo steel shows an overall trend of first decreasing and then increasing, reaching a minimum value of 43.60% after tempering for 80 h. The percentage reduction of area of 4.6Mo steel does not show significant change within the tempering time range of 0-50 h, and then decreases, reaching a maximum value of 62.16% after tempering for 0 h and a minimum value of 51.84% after tempering for 80 h. With the extension of tempering time, the number and size of Fe₃C phase in the 0Mo tested steel decrease, while the size of M₂₃C₆ phase increases, growing from 25-42 nm after tempering for 10 h to 167-333 nm after tempering for 100 h. As the tempering time increases, there is no significant change in the size of M₂C phase in the 4.6Mo tested steel, but the quantity increases, however, the quantity of M₂₃C₆ phase does not change significantly, but the size increases slightly. The addition of Mo has a significant impact on the nucleation and growth mechanism of carbides, which can improve the tempering stability of the tested steel.

Key words: heat-resistant bearing steel, high-temperature long-term mechanical properties, microstructure evolution, thermal stability

中图分类号:

TG142.1

郭春成, 李海宏, 曾西军, 周锴, 信振飞, 迟宏宵, 马党参. Mo对耐热轴承钢高温长时力学性能及组织演变的影响[J]. 金属热处理, 2025, 50(5): 51-56.

Guo Chuncheng, Li Haihong, Zeng Xijun, Zhou Kai, Xin Zhenfei, Chi Hongxiao, Ma Dangshen. Effect of Mo on high-temperature long-term mechanical properties and microstructure evolution of a heat-resistant bearing steel[J]. Heat Treatment of Metals, 2025, 50(5): 51-56.

参考文献

[1] Zhou L, Tang G, Ma X, et al. Relationship between microstructure and mechanical properties of M50 ultra-high strength steel via quenching-partitioning-tempering process[J]. Materials Characterization, 2018, 146: 258-266.
[2] Su Y, Wang J X, Yu X F, et al. Effect of deep tempering on microstructure and hardness of carburized M50NiL steel[J]. Journal of Materials Research and Technology, 2021, 14: 1080-1088.
[3] 信振飞. Cr、Ni含量对高强耐热齿轮轴承钢强韧性影响研究[D]. 昆明: 昆明理工大学, 2023.
[4] Li Y, Yan W, Cotton J D, et al. A new 1.9 GPa maraging stainless steel strengthened by multiple precipitating species[J]. Materials and Design, 2015, 82: 56-63.
[5] Zhang Y, Zhan D, Qi X, et al. Effect of tempering temperature on the microstructure and properties of ultrahigh-strength stainless steel[J]. Journal of Materials Research and Technology, 2019, 35(7): 1240-1249.
[6] Zeng T Y, Li W, Wang N M, et al. Microstructural evolution during tempering and intrinsic strengthening mechanisms in a low carbon martensitic stainless bearing steel[J]. Materials Science and Engineering A, 2022, 836: 142736.
[7] Chen X F, Zheng L J, Feng S C, et al. Tempering influence on microstructural evolution and mechanical properties in a core of CSS-42L bearing steel[J]. Materials Science and Engineering A, 2022, 861: 144233.
[8] Zhou P W, Yang W L, Wu Y C, et al. Characterization of microstructural evolution with pre-strain in BG801 bearing steel: Grain, carbides, retained austenite and martensite[J]. Vacuum, 2023, 216: 112354.
[9] 李彬周. 20CrNi2Mo钢热轧过程中贝氏体组织控制[D]. 沈阳: 东北大学, 2015.
[10] Shi R J, Wang Z D, Qiao L J, et al. Microstructure evolution of in-situ nanoparticles and its comprehensive effect on high strength steel[J]. Journal of Materials Science & Technology, 2019, 35: 1940-1950.
[11] 殷军伟. 碳含量对Cr-Mo-V系热作模具钢高温性能的影响研究[D]. 昆明: 昆明理工大学, 2020.

[1]	牛雪梅, 景林旺, 黄尧, 闫献国, 陈峙. 深冷处理对6061铝合金微观组织和力学性能的影响[J]. 金属热处理, 2025, 50(5): 175-180.
[2]	黄嘉良, 徐烨玲, 侯翔益, 王冲, 段然, 黄烁, 廉心桐. 700 ℃长期时效对GH4706合金组织及力学性能的影响[J]. 金属热处理, 2025, 50(4): 106-113.
[3]	曹萍, 王国波, 陈登武, 苏诚. 热处理对RAFM钢挤压管组织和力学性能的影响[J]. 金属热处理, 2025, 50(4): 207-212.
[4]	金帅, 王会强, 崔建英, 王艳山, 闫学兰, 李文翔. 基于BP神经网络预测热处理后35CrMoA钢的低温冲击性能[J]. 金属热处理, 2025, 50(3): 125-131.
[5]	张盛豪, 王宝, 李思佳, 肖美美, 周建安. 奥氏体逆相变退火温度对含铜中锰钢组织和性能的影响[J]. 金属热处理, 2025, 50(2): 96-101.
[6]	彭杏娜, 丛相州, 彭先宽, 涂德军, 乔亚霞. P92耐热钢弯头高温持久过程组织表征[J]. 金属热处理, 2025, 50(1): 230-235.
[7]	赵勇桃, 吴银虎, 鲁海涛, 王瑞, 雷丙旺. 不同等温温度下P92钢的组织演变[J]. 金属热处理, 2024, 49(9): 47-50.
[8]	蒙品品, 张晓波. 退火处理对纯铜微观组织及力学性能的影响[J]. 金属热处理, 2024, 49(7): 267-273.
[9]	郭春成, 亓海全, 迟宏宵, 谷金波, 刘安奇, 王为民. 1900 MPa级耐热轴承钢的热变形行为与热加工图[J]. 金属热处理, 2024, 49(4): 26-34.
[10]	王成宇, 安腾, 谢兴飞, 吕少敏, 曲敬龙. GH4730合金累积变形过程中的组织演变规律[J]. 金属热处理, 2024, 49(4): 88-94.
[11]	张禹, 于金瑞, 于鑫泓, 冯以盛, 张云山, 赵而团. 等温淬火温度对50CrVA钢组织与性能的影响[J]. 金属热处理, 2024, 49(3): 28-32.
[12]	童炀, 张婧, 辛文彬, 罗果萍, 彭军, 侯蹬云. Nb含量对V-Ti-N工程结构用钢连续冷却转变规律及组织性能的影响[J]. 金属热处理, 2024, 49(3): 236-243.
[13]	张坛, 李昊彧, 定巍, 李岩. 预备组织对中锰钢临界退火组织演变和力学性能的影响[J]. 金属热处理, 2024, 49(10): 8-17.
[14]	郑昊青, 孟少博, 任武彬, 孙新军. 两相区退火时间对Fe-0.16C-0.2Si-4.78Mn-0.24Mo中锰钢组织和力学性能的影响[J]. 金属热处理, 2024, 49(10): 133-139.
[15]	李冰伟, 杨西荣, 刘晓燕, 王敬忠, 刘丹, 余承希, 白天育. 基于Laasraoui-Jonas位错密度模型的GH3625合金组织演变[J]. 金属热处理, 2024, 49(10): 202-210.

Mo对耐热轴承钢高温长时力学性能及组织演变的影响

Effect of Mo on high-temperature long-term mechanical properties and microstructure evolution of a heat-resistant bearing steel

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价