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Journal of Materials Engineering and Performance

Erschienen in:

15.01.2021

Relationship Between the Microstructural Evolution and Wear Behavior of U71Mn Rail Steel

verfasst von: Jinzhi Pan, Lin Chen, Chunpeng Liu, Guanzhen Zhang, Ruiming Ren

Erschienen in: Journal of Materials Engineering and Performance | Ausgabe 2/2021

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Abstract

During train operation in a wheel-rail system, the service lives of the wheel and rail materials are heavily influenced by microstructural evolution. This study investigated the relationship between microstructural evolution and the wear properties of U71Mn rail steel under conditions of dry sliding wear using an MRH-5A wear tester. The results demonstrated that tribological white etching layers (T-WELs), which comprise nanocrystalline α-Fe and fine carbide, are formed after a certain number of cycles. The T-WEL thickness increased with the number of cycles; however, more cycles caused T-WEL flaking, which resulted in a reduced T-WEL length. The high microhardness of T-WELs (approximately 950 HV) is mainly attributed to ferrite grain refinement and cementite dissolution. During initial wear, the existence of grinding marks on the surfaces of the samples indicated an obvious increase in the wear loss of the steel. The high microhardness of the T-WELs can enhance wear resistance; thus, as the number of cycles was increased, the wear loss of the steel was reduced. At this point, an adhesive wear mechanism acted on the rail steel. The formation of fatigue cracks at the interface between the T-WEL and the plastic deformation layer induces T-WEL flaking, which increases wear loss. Consequently, after 6000 cycles, wear loss increased as the wear mechanism changed to fatigue wear. It is confirmed that T-WEL flaking is the primary cause of wear failure in U7Mn rail steel.

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H. Meng, M. Huang, and W.M. Zhai, Analysis and Investigation for the Flange Partial Wear of Locomotive, Railw. Locomot. Car, 2006, 26, p 4–7

M. Steenbergen, Squat Formation and Rolling Contact Fatigue in Curved Rail Track, Eng. Fract. Mech., 2015, 143, p 80–96CrossRef

C.P. Liu, X.J. Zhao, P.T. Liu, C. Su, and R.M. Ren, Influence of Slip Ratio on Worn-Surface Microstructure and Fatigue Wear Behavior of D2 Wheel Steel, J. Iron. Steel Res. Int., 2018, 25, p 1278–1286CrossRef

X.J. Zhao, P.T. Liu, J.Z. Pan, and R.M. Ren, Influence of Contact Stress on Surface Microstructure and Wear Property of D2/U71Mn Wheel-Rail Material, Materials, 2019, 12, p 3268CrossRef

L. Ma, C.G. He, X.J. Zhao, J. Guo, Y. Zhu, W.J. Wang, Q.Y. Liu, and X.S. Jin, Study on Wear and Rolling Contact Fatigue Behaviors of Wheel/Rail Materials Under Different Slip Ratio Conditions, Wear, 2016, 366–367, p 13–26CrossRef

G.Z. Zhang, C.P. Liu, H. Zhang, Q. Li, and R.M. Ren, Study on Wear Properties of J11 Wheel Steel with Nonuniform Microstructure, J. Mater. Eng. Perform., 2020, 1, p 1. https://doi.org/10.1007/s11665-020-05183-0CrossRef

Y. Hu, C.R. Su, L.C. Guo, Q.Y. Liu, J. Guo, Z.R. Zhou, and W.J. Wang, Effect of Rolling Direction on Microstructure Evolution of CL60 Wheel Steel, Wear, 2019, 424–425, p 203–215CrossRef

H. Chen, Y.Z. Ji, C. Zhang, W.B. Liu, H. Chen, Z.G. Yang, L.Q. Chen, and L. Chen, Understanding Cementite Dissolution in Pearlitic Steels Subjected to Rolling-Sliding Contact Loading: A Combined Experimental and Theoretical Study, Acta Mater., 2017, 141, p 193–205CrossRef

X. Wang, X.H. Wei, X.L. Hong, J.Y. Yang, and W.R. Wang, Formation of Sliding Friction-Induced Deformation Layer with Nanocrystalline Structure in T10 Steel Against 20CrMnTi Steel, Appl. Surf. Sci., 2013, 280, p 381–387CrossRef

10.

A. Emge, S. Karthikeyan, and D. Rigney, The Effects of Sliding Velocity and Sliding Time on Nanocrystalline Tribolayer Development and Properties in Copper, Wear, 2009, 267, p 562–567CrossRef

11.

J.G. Li, M. Umemoto, Y. Todaka, and K. Tsuchiya, Nanocrystalline Structure Formation in Carbon Steel Introduced by High Speed Drilling, Mater. Sci. Eng., A, 2006, 435–436, p 383–388CrossRef

12.

Y.D. Chen, R.M. Ren, X.J. Zhao, C.H. Chen, and R. Pan, Study on the Surface Microstructure Evolution and Wear Property of Bainitic Rail Steel Under Dry Sliding Wear, Wear, 2020, 448–449, p 203217CrossRef

13.

R. Pan, R.M. Ren, C.H. Chen, and X.J. Zhao, Formation of Nanocrystalline Structure in Pearlitic Steels by Dry Sliding Wear, Mater. Charact., 2017, 132, p 397–404CrossRef

14.

R. Pan, R.M. Ren, C.H. Chen, and X.J. Zhao, The Microstructure Analysis of White Etching Layer on Treads of Rails, Eng Fail Analy., 2017, 82, p 39–46CrossRef

15.

H.W. Zhang, S. Ohsaki, S. Mitao, M. Ohnuma, and K. Hono, Microstructural Investigation of White Etching Layer on Pearlite Steel Rail, Mater. Sci. Eng., A, 2006, 421, p 191–199CrossRef

16.

T. Kato, A. Sugeta, and E. Nakayama, Investigation of Influence of White Layer Geometry on Spalling Property in Rail Wheel Steel, Wear, 2011, 271, p 400–407CrossRef

17.

J.W. Seo, S.J. Kwon, H.K. Jun, and D.H. Lee, Numerical Stress Analysis and Rolling Contact Fatigue of White Etching Layer on Rail Steel, Int. J. Fatigue, 2011, 33, p 203–211CrossRef

18.

H.H. Ding, C.R. Su, W.J. Wang, Z.B. Cai, D.Z. Wang, J. Guo, Q.Y. Liu, and Z.R. Zhou, Investigation on the Rolling Wear and Damage Properties of Laser Discrete Quenched Rail Material with Different Quenching Shapes and Patterns, Surf Coat Tech, 2019, 378, p 124991CrossRef

19.

S.V. Konovalov, V.E. Kormyshev, V.E. Gromov, Y.F. Ivanov, E.V. Kapralov, and A.P. Semin, Formation Features of Structure-Phase States of Cr–Nb–C–V Containing Coatings on Martensitic Steel, J Surf Investig, 2016, 10, p 1119–1124CrossRef

20.

Y. Zhou, J.F. Peng, Z.P. Luo, B.B. Cao, X.S. Jin, and M.H. Zhu, Phase and Microstructural Evolution in White Etching Layer of a Pearlitic Steel During Rolling–Sliding Friction, Wear, 2016, 362–363, p 8–17CrossRef

21.

V.A. Grishunin, V.E. Gromov, Y.F. Ivanov, A.D. Teresov, and S.V. Konovalov, Evolution of the Phase Composition and Defect Substructure of Rail Steel Subjected to High-Intensity Electron-Beam Treatment, J Surf Investig, 2013, 7, p 990–995CrossRef

22.

H. Chen, C. Zhang, W.B. Liu, Q.H. Li, H. Chen, Z.G. Yang, and Y.Q. Weng, Microstructure Evolution of a Hypereutectoid Pearlite Steel Under Rolling-Sliding Contact Loading, Mater. Sci. Eng., A, 2016, 655, p 50–59CrossRef

23.

GB/T 12444-2006. Metallic materials—Wear test method—Block-on-ring sliding wear test, China Iron and Steel Association, 2006.

24.

M. Scherge, D. Shakhvorostov, and K. Pohlmann, Fundamental Wear Mechanism of Metals, Wear, 2003, 255, p 395–400CrossRef

25.

J.E. Garnham and C.L. Davis, The role of Deformed Rail Microstructure on Rolling Contact Fatigue Initiation, Wear, 2008, 265, p 1363–1372CrossRef

26.

B.F. Zhang, W.C. Shen, Y.J. Liu, X.Y. Tang, and Y.F. Wang, Microstructure of Surface White Layers and Internal White Adiabatic Shear Band, Wear, 1997, 211, p 164–168CrossRef

27.

R.I. Carroll and J.H. Beynon, Rolling Contact Fatigue of White Etching Layer Part 2: Numerical Results, Wear, 2007, 262, p 1267–1273CrossRef

28.

B. Yao, Z. Han, and K. Lu, Dry sliding Tribological Properties and Subsurface Structure of Nanostructured Copper at Liquid Nitrogen Temperature, Wear, 2013, 301, p 608–614CrossRef

29.

Y.J. Li, P. Choi, C. Borchers, S. Westerkamp, S. Goto, D. Raabe, and R. Kirchheim, Atomic-Scale Mechanisms of Deformation-Induced Cementite Decomposition in Pearlite, Acta Mater., 2011, 59, p 3965–3977CrossRef

30.

N.R. Tao, Z.B. Wang, W.P. Tong, M.L. Sui, J. Lu, and K. Lu, An Investigation of Surface Nanocrystallization Mechanism in Fe Induced by Surface Mechanical Attrition Treatment, Acta Mater., 2002, 50, p 4603–4616CrossRef

31.

S.B. Newcomb and W.M. Stobbs, A Transmission Electron Microscope Study of the White-Etching Layer on a Rail Head, Mater. Eng., 1984, 66, p 95–204

32.

Y. Ivanisenko, W. Lojkowski, R.Z. Valiev, and H.J. Fecht, The Mechanism of Formation of Nanostructure and Dissolution of Cementite in a Pearlitic Steel During High Pressure Torsion, Acta Mater., 2003, 51, p 5555–5570CrossRef

33.

B. Venkataraman and G. Sundararajan, The Sliding Wear Behaviour of Al-SiC Particulate Composites-II: The Characterization of Subsurface Deformation and Correlation with Wear Behaviour, Acta Mater., 1996, 44, p 461–473CrossRef

34.

K. Hono, M. Ohnuma, M. Murayama, S. Nishida, A. Yoshie, and T. Takahashi, Cementite Decompposition in Heavily Drawn Pearlite Steel Wire, Scripta Mater., 2001, 44, p 977–983CrossRef

35.

G. Langford, Deformation of Pearlite, Metall. Trans. A, 1977, 8, p 861–875CrossRef

36.

G. Baumann, H.J. Fecht, and S. Liebelt, Formation of White-Etching Layers on Rail Treads, Wear, 1996, 191, p 133–140CrossRef

37.

N. Petch, The Cleavage Strength of Polycrystals, Iron Steel Inst, 1953, 174, p 25–28

38.

C.M. Liu, J.J. Wang, R.R. Lin, W.F. Cui, and Y.G. Bai, The Role of Slight Carbon in Grain Refinement Strength for Steel Material, Mater. Sci. Tech., 2001, 9, p 301–304

39.

Q.L. Lian, G.Y. Deng, A. Al-Juboori, H.J. Li, Z.M. Liu, X. Wang, and H.T. Zhu, Crack Propagation Behavior in White Etching Layer on Rail Steel Surface, Eng. Fail. Anal., 2019, 104, p 816–829CrossRef

Titel: Relationship Between the Microstructural Evolution and Wear Behavior of U71Mn Rail Steel
verfasst von: Jinzhi Pan
Lin Chen
Chunpeng Liu
Guanzhen Zhang
Ruiming Ren
Publikationsdatum: 15.01.2021
Verlag: Springer US
Erschienen in: Journal of Materials Engineering and Performance / Ausgabe 2/2021
Print ISSN: 1059-9495
Elektronische ISSN: 1544-1024
DOI: https://doi.org/10.1007/s11665-021-05452-6

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