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Abstract
We performed thermal simulation experiments of double-pass deformation of hypereutectoid rails with different microalloying elements at a cooling rate of 1°C/s and deformation of 80% to explore the influence of rare-earth and microalloying elements on the structure of hypereutectoid rails and optimize the composition design of hypereutectoid rails. Scanning electron microscopy, transmission electron microscopy, X-ray diffraction, and other characterization techniques were employed to quantitatively analyzed the effects of different microalloying elements, including rare-earth elements, on pearlite lamellar spacing, cementite characteristics, and dislocation density. It was found that the lamellar spacing was reduced by adding various microalloying elements. Cementite lamellar thickness decreased with the refinement of pearlite lamellar spacing while the cementite content per unit volume increased. Local cementite spheroidization, dispersed in the ferrite matrix in granular form and thus playing the role of dispersion strengthening, was observed upon adding cerium (Ce). The contributions of dislocation density to the alloy strength of four steel sheet samples with and without the addition of nickel, Ce, and Ce–copper (Cu) composite were 26, 27, 32, and 37 MPa, respectively, indicating that the Ce-Cu composite had the highest dislocation strengthening effect. The Ce−Cu composite has played a meaningful role in the cementite characteristics and dislocation strengthening, which provides a theoretical basis for optimizing the composition design of hypereutectoid rails in actual production conditions.
Keywords
microalloying elements
/
rare earth
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hypereutectoid rail
/
cementite
/
dislocation
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Yuheng Dai, Wenqian Zhao, Xirong Bao, Lin Chen.
Effects of Rare-earth and Microalloying Elements on the Microstructure Characteristics of Hypereutectoid Rails.
Journal of Wuhan University of Technology Materials Science Edition, 2023, 38(3): 682-688 DOI:10.1007/s11595-023-2746-9
| [1] |
Zhang Y, Li C, Zhou Q, et al. Test Study on Hypereutectoid Rail for Heavy Haul Railway in China[J]. China Railway Science, 2013, 34(6): 1-7.
|
| [2] |
Olivares R O, Garcia C I, Deardo A, et al. Advanced Metallurgical Alloy Design and Thermomechanical Processing for Rails Steels for North American Heavy Haul Use[J]. Wear, 2011, 271(1): 364-373.
|
| [3] |
Shu D. Mechanical Properties of Engineering Materials (2nd Edition)[M], 2007 Beijing: China Machine Press.
|
| [4] |
Zhu M, Xu G, Hou R, et al. Study on Wear Behavior of U68CuCr and U75V Track Steel[J]. Surface Technology, 2017, 46(10): 149-155.
|
| [5] |
Dey I, Chandra S, Saha R, et al. Effect of Nb Micro-Alloying on Microstructure and Properties of Thermo-Mechanically Processed High Carbon Pearlitic Steel[J]. Materials Characterization, 2018, 140: 45-54.
|
| [6] |
CAO J, ZHAO A, LIU J, et al. Effect of Nb on Microstructure and Mechanical Properties in Non-Magnetic High Manganese Steel[J]. Iron Steel Res., 2014(6): 600–605
|
| [7] |
Jiao Z B, Luan J H, Zhang Z W, et al. Synergistic Effects of Cu and Ni on Nanoscale Precipitation and Mechanical Properties of High-Strength Steels[J]. Acta Materialia, 2013, 61(16): 5 996-6 005.
|
| [8] |
Xiang Y, Chen Z G, Wei X, et al. Influence of Ce on Microstructure and Properties of Highcarbon High-Boron Steel[J]. Rare Metal. Mater. Eng., 2015, 44(6): 1 335-1 339.
|
| [9] |
Wei Z, Liang Y, Liang Y, et al. Effect of Pearlite Lamellar and Proeutectoid Ferrite on Fracture Toughness in High Carbon Steel[J]. Journal of Material Heat Treatment, 2016, 37(01): 126-132.
|
| [10] |
Cen Y, Chen L, Dong R, et al. Effect of Quenching Rate on Fatigue Crack Growth of Hypereutectoid Rail Steel[J]. Journal of Materials Science, 2020, 55(30): 15 033-15 042.
|
| [11] |
SUN Shuhua. Effect of Microstructure on Fatigue Crack Growth Rate of Pearlite Steel[J]. Physical test, 2004 (02): 7–10
|
| [12] |
Cen Y, Chen L, Chang G, et al. Transformation Characteristics and Microstructure of Rail Under Low Stress During Continuous Cooling[J]. Journal of Wuhan University of Technology -Materials Science Edition, 2021, 36(02): 269-279.
|
| [13] |
Sano N Y, Daitoh T. Hamada. Microstructural Changes of Cementite and Ferrite in Heavily Drawn Pearlitic Wires[C]. Materials Science Forum, 2003, 426: 1 231-1 236.
|
| [14] |
Hong M H, Hono K, Reynolds W T, et al. Atom Probe and Transmission Electron Microscopy Investigations of Heavily Drawn Pearlitic Steel Wire[J]. Metallurgical and Materials Transactions A, 1999, 30(13): 717-727.
|
| [15] |
Feng L, Wu K, Qiao W, et al. Effect of Nb on Pearlite Spheroidization of High Carbon Steel[J]. Journal of Iron and Steel Research, 2020, 32(08): 734-739.
|
| [16] |
Williamson G K, Smallman R E III. Dislocation Densities in Some Annealed and Cold-Worked Metals from Measurements on the X-ray Debye-Scherrer Spectrum[J]. Philosophical Magazine, 1956, 1(1): 34-46.
|
| [17] |
Kril C E, Birringer R. Estimating Grain-Size Distributions in Nanocrystalline Materials from X-ray Diffraction Profile Analysis[J]. Philosophical Magazine A, 1998, 77(3): 621-640.
|
| [18] |
Jia R, Zhang Y, Zhang Y, et al. Calculation of Dislocation Density in 4H SiC Epitaxial Single Crystal by XRD[J]. Spectroscopy and Spectral Analysis, 2010, 30(07): 1 995-1 997.
|
| [19] |
Gay P, Hirsch P B, Kelly A. The Estimation of Dislocation Densities in Metals from X-ray Data[J]. Acta Metallurgica, 1953, 1(3): 315-319.
|
