Research progress on evolution of carbides in bearing steel under magnetic field

doi:10.13251/j.issn.0254-6051.2025.05.006

Abstract

Abstract: Preparation of bearing steel entails casting, solidification, and solid-state phase transformation, each crucial in controlling its microstructure evolution, particularly the precipitation behavior of carbides. This precipitation behavior represents a key technical bottleneck in enhancing rolling contact fatigue properties. After decades of research, the mechanisms by which strong magnetic fields influence phase transformations in steel are becoming increasingly understood, suggesting magnetic fields as a valuable tool for structural refinement in steel. Findings show that magnetic fields can enhance melt flow and solid particle migration by altering dendrite growth and morphology, resulting in improved hardness and wear resistance. Furthermore, during spheroidizing annealing, magnetic fields can promote carbide dissolution and uniform refinement, increase dislocation diffusion driving force, and optimize the formation of martensite and carbide precipitation during quenching and tempering processes. However, the response mechanisms of carbide electronic structures in strong magnetic fields remain unclear, with practical challenges such as high costs and limited processing capacity. Thus, further exploration is needed to make magnetic field applications in bearing steel and other high-performance steels more cost-effective and scalable.

Key words: bearing steel, magnetic field, carbides, solidification phase transformation, spheroidizing annealing, quenching and tempering

CLC Number:

TG142.1

Tan Xinyang, Chen Yujing, Hou Tingping, Wu Kaiming. Research progress on evolution of carbides in bearing steel under magnetic field[J]. Heat Treatment of Metals, 2025, 50(5): 33-39.

References

[1] 国家制造强国建设战略咨询委员会, 中国工程院战略咨询中心. 《中国制造2025》重点领域技术创新绿皮书[M]. 北京: 电子工业出版社, 2018.
[2] 杨平, 罗海文. 改进型M50高温用轴承钢的设计与研发[J]. 金属热处理, 2018, 43(8): 1-7.
Yang Ping, Luo Haiwen. Design and development of improved M50 high-temperature bearing steel[J]. Heat Treatment of Metals, 2018, 43(8): 1-7.
[3] Feng Q, Li J, Zeng Y, et al. Effect of Cr atom doping on the carbide stability and mechanical properties of high carbon chromium bearing steels[J]. Journal of Materials Research and Technology, 2023, 23: 5710-5722.
[4] Yang L, Xue W, Gao S, et al. Rolling contact fatigue behaviour of M50 bearing steel with rare earth addition[J]. International Journal of Fatigue, 2023, 177: 107940.
[5] Chong X, Jiang Y, Feng J. Exploring the intrinsic ductile metastable Fe-C compounds: Complex chemical bonds, anisotropic elasticity and variable thermal expansion[J]. Journal of Alloys and Compounds, 2018, 745: 196-211.
[6] Long X, Zhang F, Yang Z, et al. Study on microstructures and properties of carbide-free and carbide-bearing bainitic steels[J]. Materials Science and Engineering A, 2018, 715: 10-16.
[7] 谢亚飞, 侯廷平, 于涛, 等. 合金碳化物M₂₃C₆对CLAM钢晶界拉伸性能的影响机理研究[J]. 武汉科技大学学报, 2023, 46(6): 409-417.
Xie Yafei, Hou Tingping, Yu Tao, et al. Mechanism of alloy carbide M₂₃C₆ influencing grain boundary tensile properties of CLAM steel[J]. Journal of Wuhan University of Science and Technology, 2023, 46(6): 409-417.
[8] 袁志钟. 金属材料学[M]. 3版. 北京: 化学工业出版社, 2019.
[9] 冯路路, 吴开明, 乔文玮, 等. 轴承钢珠光体球化的研究现状及发展趋势[J]. 中国冶金, 2020, 30(9): 110-118.
Feng Lulu, Wu Kaiming, Qiao Wenwei, et al. Research status and developing tendency of bearing steel spheroidization of pearlite[J]. China Metallurgy, 2020, 30(9): 110-118.
[10] 申丽娟, 麻永林, 谢港生, 等. 脉冲磁场对GCr15轴承钢网状碳化物的影响[J]. 材料热处理学报, 2024, 45(5): 114-121.
Shen Lijuan, Ma Yonglin, Xie Gangsheng, et al. Effect of pulsed magnetic field on network carbides in GCr15 bearing steel[J]. Transactions of Materials and Heat Treatment, 2024, 45(5): 114-121.
[11] 李闪闪, 陈云, 巩桐兆, 等. 冷速对高碳铬轴承钢液析碳化物凝固析出机制的影响[J]. 金属学报, 2022, 58(8): 1024-1034.
Li Shanshan, Chen Yun, Gong Tongzhao, et al. Effect of cooling rate on the precipitation mechanism of primary carbide during solidification in high carbon-chromium bearing steel[J]. Acta Metallurgica Sinica, 2022, 58(8): 1024-1034.
[12] Wang F, Qian D, Hu A L, et al. Effect of high magnetic field on the microstructure evolution and mechanical properties of M50 bearing steel during tempering[J]. Materials Science and Engineering A, 2020, 771: 138623.
[13] Qiu N, Yan J, Zuo X. A novel strategy for hierarchical structure in multicomponent nano-precipitated steels by high magnetic field aging[J]. Scripta Materialia, 2021, 191: 137-142.
[14] Chen R, Kong H J, Luan J H, et al. Effect of external applied magnetic field on microstructures and mechanical properties of laser welding joint of medium-Mn nanostructured steel[J]. Materials Science and Engineering A, 2020, 792: 139787.
[15] 镇锦煌, 侯廷平, 刘杨妮, 等. 强磁场下贝氏体相变的热力学机制研究[J]. 武汉科技大学学报, 2023, 46(2): 81-86.
Zhen Jinhuang, Hou Tingping, Liu Yangni, et al. Thermodynamic mechanism of bainite transformation under strong magnetic field[J]. Journal of Wuhan University of Science and Technology, 2023, 46(2): 81-86.
[16] 谢港生. 脉冲磁场热处理对GCr15钢组织与性能的影响[D]. 包头: 内蒙古科技大学, 2023.
[17] Kakeshita T, Shimizu K, Funada S, et al. Composition dependence of magnetic field-induced martensitic transformations in Fe-Ni alloys[J]. Acta Metallurgica, 1985, 33(8): 1381-1389.
[18] Wu G H, Hou T P, Wu K M, et al. Influence of high magnetic field on carbides and the dislocation density during tempering of high chromium-containing steel[J]. Journal of Magnetism and Magnetic Materials, 2019, 479: 43-49.
[19] Xia Z X, Zhang C, Lan H, et al. Effect of magnetic field on interfacial energy and precipitation behavior of carbides in reduced activation steels[J]. Materials Letters, 2011, 65(6): 937-939.
[20] Fang C M, Huis van M A, Sluiter M H F, et al. Stability, structure and electronic properties of γ-Fe₂₃C₆ from first-principles theory[J]. Acta Materialia, 2010, 58: 2968-2977.
[21] Hou T P, Wu K M. Alloy carbide precipitation in tempered 2.25Cr-Mo steel under high magnetic field[J]. Acta Materialia, 2013, 61(6): 2016-2024.
[22] Zhou Z N, Wu K M. Molybdenum carbide precipitation in an Fe-C-Mo alloy under a high magnetic field[J]. Scripta Materialia, 2009, 61(7): 670-673.
[23] Zhang D, Hou T, Liang X, et al. Insights into the assessment of the magnetic-field-induced precipitation behavior of alloy carbides M₇C₃ in steels[J]. Materials and Design, 2022, 221: 111023.
[24] Hou T P, Wu K M. The effect of high magnetic field on metal solute substitution in M₂₃C₆ alloy carbide[J]. Scripta Materialia, 2012, 67(6): 609-612.
[25] 温斌, 姚山, 李廷举, 等. 连铸坯中缩敏感系数的研究[J]. 铸造技术, 2004, 25(9): 673-675.
Wen Bin, Yao Shan, Li Tingju, et al. Study on the centerline shrinkage sensitivity coefficient of slab ingot[J]. Foundry Technology, 2004, 25(9): 673-675.
[26] 朱苗勇, 林启勇. 连铸坯的轻压下技术[J]. 鞍钢技术, 2004(1): 1-6.
Zhu Miaoyong, Lin Qiyong. Light reduction technology for continuous casting slab[J]. Angang Technology, 2004(1): 1-6.
[27] Flemings M C. Our understanding of macrosegregation: Past and present[J]. ISIJ International, 2000, 40(9): 833-841.
[28] Li X, Gagnoud A, Fautrelle Y, et al. Dendrite fragmentation and columnar-to-equiaxed transition during directional solidification at lower growth speed under a strong magnetic field[J]. Acta Materialia, 2012, 60(8): 3321-3332.
[29] Li X, Gagnoud A, Ren Z, et al. Investigation of thermoelectric magnetic convection and its effect on solidification structure during directional solidification under a low axial magnetic field[J]. Acta Materialia, 2009, 57(7): 2180-2197.
[30] Harada H, Toh T, Ishii T, et al. Effect of magnetic field conditions on the electromagnetic braking efficiency[J]. ISIJ International, 2001, 41(10): 1236-1244.
[31] 侯渊, 任忠鸣, 王江, 等. 纵向静磁场对定向凝固GCr15轴承钢柱状晶向等轴晶转变的影响[J]. 金属学报, 2018, 54(5): 801-808.
Hou Yuan, Ren Zhongming, Wang Jiang, et al. Effect of longitudinal static magnetic field on the columnar to equiaxed transition in directionally solidified GCr15 bearing steel[J]. Acta Metallurgica Sinica, 2018, 54(5): 801-808.
[32] Dold P, Szofran F R, Benz K W. Thermoelectromagnetic convection in vertical Bridgman grown germanium-silicon[J]. Journal of Crystal Growth, 2006, 291(1): 1-7.
[33] Lehmann P, Moreau R, Camel D, et al. Modification of interdendritic convection in directional solidification by a uniform magnetic field[J]. Acta Materialia, 1998, 46(11): 4067-4079.
[34] 黄大伟. 电磁搅拌作用下轴承钢凝固组织形态演变的研究[D]. 沈阳: 东北大学, 2011.
[35] Sun Z, Xia Z, Zhang M, et al. The effect of alternative magnetic field on solidification structure improvement and primary carbide refinement in M50 ingots produced by vacuum arc remelting[J]. Journal of Materials Research and Technology, 2024, 30: 5219-5231.
[36] Zhong Y B, Qiang L I, Fang Y P, et al. Effect of transverse static magnetic field on microstructure and properties of GCr15 bearing steel in electroslag continuous casting process[J]. Materials Science and Engineering A, 2016, 660: 118-126.
[37] Li C, Li Z, Ren J, et al. Microstructure and properties of 1.0C-1.5Cr bearing steel in processes of hot rolling, spheroidization, quenching, and tempering[J]. Steel Research International, 2019, 90: 1800470.
[38] 许磊, 陈瑜, 韩彦光, 等. GCr15轴承钢球化退火研究现状[J]. 热加工工艺, 2013, 42(14): 11-14.
Xu Lei, Chen Yu, Han Yanguang, et al. Recent research on spheroidization of GCr15 bearing steel[J]. Hot Working Technology, 2013, 42(14): 11-14.
[39] 邓素怀, 严春莲, 张慧峰, 等. 球化处理对轴承钢碳化物网的影响[J]. 热加工工艺, 2017, 46(12): 218-221.
Deng Suhuai, Yan Chunlian, Zhang Huifeng, et al. Effect of spheroidizing on carbide network in bearing steel[J]. Hot Working Technology, 2017, 46(12): 218-221.
[40] Yin H, Wu Y, Liu D, et al. Rolling contact fatigue-related microstructural alterations in bearing steels: A brief review[J]. Metals, 2022, 12(6): 910.
[41] Hao J, Zhang H, Zhang X, et al. Accelerated carbon atoms diffusion in bearing steel using electropulsing to reduce spheroidization processing time and improve microstructure uniformity[J]. Steel Research International, 2020, 91(7): 2000041.
[42] 谢港生, 邢淑清, 申丽娟, 等. 脉冲磁场对GCr15钢球化退火过程中碳化物析出的影响[J]. 金属热处理, 2023, 48(4): 118-123.
Xie Gangsheng, Xing Shuqing, Shen Lijuan, et al. Effect of pulsed magnetic field on precipitation of carbides during spheroidizing annealing of GCr15 steel[J]. Heat Treatment of Metals, 2023, 48(4): 118-123.
[43] 申丽娟, 谢港生, 麻永林, 等. 电磁能条件下球化退火过程中 GCr15 轴承钢碳化物的溶解行为[J]. 金属热处理, 2022, 47(8): 40-45.
Shen Lijuan, Xie Gangsheng, Ma Yonglin, et al. Carbide dissolution behavior in GCr15 bearing steel during spheroidization annealing under condition of electromagnetic energy[J]. Heat Treatment of Metals, 2022, 47(8): 40-45.
[44] Li Y, Li C, Chen S, et al. Effect of spheroidizing annealing in combination with alternating magnetic field on microstructure and mechanical properties of GCr15 bearing steel[J]. ISIJ International, 2022, 62(6): 1275-1282.
[45] Song Y, Yu C, Miao X, et al. Tribological performance improvement of bearing steel GCr15 by an alternating magnetic treatment[J]. Acta Metallurgica Sinica (English Letters), 2017, 30(10): 957-964.
[46] 刘雪华. 减小GCr15轴承套圈热处理变形的工艺研究[J]. 热加工工艺, 2007, 36(10): 62-64.
Liu Xuehua. Study on process for decreasing heat treatment distortion of GCr15 bear ring[J]. Hot Working Technology, 2007, 36(10): 62-64.
[47] Mukherjee S. Boundary Element Methods in Creep and Fracture[M]. London, New Jersey: Applied Science Publishers, 1982.
[48] 徐祖耀. 马氏体相变的分类[J]. 金属学报, 1997, 33(1): 45-53.
Xu Zuyao. Classification of the martensitic transformations[J]. Acta Metallurgica Sinica, 1997, 33(1): 45-53.
[49] 陈龙. 强磁场和回火温度对高铬钢碳化物析出和位错密度的影响[D]. 武汉: 武汉科技大学, 2018.
[50] Sadovskii V, Rodigin N, Smirnov L, et al. The question of the influence of magnetic field on martensitic transformation in steel[J]. Fizika Metallov I Metallovedenie, 1961, 12: 302-304.
[51] Xie G, Shen L, Xing S, et al. Effect of pulsed magnetic field on quenched heat treatment of GCr15 steel[J]. JOM, 2023, 75(7): 2256-2264.
[52] Li Y C, Chen S Y, Zhu F H, et al. Effect of high magnetic field in combination with high-temperature tempering on microstructures and mechanical properties of GCr15 bearing steel[J]. Metals, 2022, 12(8): 1293.
[53] Qian C, Li K, Rui S S, et al. Magnetic induced re-dissolution and microstructure modifications on mechanical properties of Cr₄Mo₄V steel subjected to pulsed magnetic treatment[J]. Journal of Alloys and Compounds, 2021, 881: 160471.
[54] 张东, 侯廷平, 郑一航, 等. 强磁场下钢中析出相演变规律研究进展[J]. 铸造技术, 2022, 43(8): 615-624.
Zhang Dong, Hou Tingping, Zheng Yihang, et al. Research progress on evolution of precipitate phases in steel under high magnetic field[J]. Foundry Technology, 2022, 43(8): 615-624.
[55] Zhu F, Jiang D, Sun S, et al. Effect of alternating magnetic field on microstructure evolution and mechanical properties of M50 bearing steel during tempering process[J]. Journal of Materials Research and Technology, 2023, 26: 4516-4525.