Effect of high pressure on the melting and solidifying behavior of a railway frog steel

Sujun Wu; Dong Ma; Bo Han; Lei Chen

doi:10.1007/s11595-017-1691-x

Journal of Wuhan University of Technology Materials Science Edition ›› 2017, Vol. 32 ›› Issue (4) : 921 -925. DOI: 10.1007/s11595-017-1691-x

Metallic Materials

Effect of high pressure on the melting and solidifying behavior of a railway frog steel

Sujun Wu ¹^,^{^a}
, Dong Ma ¹
, Bo Han ¹
, Lei Chen ¹

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Abstract

Microstructural evolutions of the railway frog steel solidified under different pressure were studied using OM, FEGSEM, and TEM. The influences of pressure on the solidification, grain sizes, and morphology of carbides of the steel were analyzed. It is found that the melting point of the steel increases with the pressure and the solidified microstructure under high pressure does not vary significantly with the melting temperature. The experimental results show that the solidified microstructure consisting of complete equiaxed dendrites is remarkably refined through the increase of pressure, with the mean dendrite arm spacing of about 24, 18, and 8 μm under 3, 6, and 10 GPa, respectively. It is also revealed by TEM observation that the precipitates change from needle-like and rhombic carbide (M₃C) forms during normal (atmospheric) pressure solidification into nodulized hexagonal precipitate M₇C₃ at 3 GPa, and M₂₃C₆ at 6 GPa and 10 GPa, which is associated with the undercooling and distribution of the trace elements. The diameter of the precipitates is between 80 nm and 200 nm.

Keywords

high pressure / solidification / melting point / equiaxed dendrites / precipitates

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Sujun Wu, Dong Ma, Bo Han, Lei Chen. Effect of high pressure on the melting and solidifying behavior of a railway frog steel. Journal of Wuhan University of Technology Materials Science Edition, 2017, 32(4): 921-925 DOI:10.1007/s11595-017-1691-x

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References

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[1]	Yu A, Wang SP, Li NY, et al. Pressurized Solidification of Magnesium Alloy AM50A[J]. J. Mater. Process. Technol., 2007, 191: 247-250.

[2]	Phanikumar G, Chattopadhyay K. Solidification Microstructure Development [J]. Sādhanā, 2001, 26: 25-34.

[3]	Wei ZJ, Wang ZL, Wang HW, et al. Evolution of Microstructures and Phases of Al-Mg Alloy under 4GPa High Pressure[J]. J. Mater. Sci., 2007, 42: 7123-7128.

[4]	Yu XF, Zhang GZ, Wang XY, et al. Non-equilibrium Microstructure of Hyper-eutectic Al-Si Alloy Solidified under Superhigh Pressure[J]. J. Mater. Sci., 1999, 34: 4149-4152.

[5]	Ahrens TJ, Holland KG, Chen GQ. Phase Diagram of Iron, Revised-core Temperatures[J]. Geophys. Res. Lett., 2001, 29: 5402-5403.

[6]	Straumal BB, Baretzky B, Mazilkin AA, et al. Formation of Nano Grained Structure and Decomposition of Supersaturated Solid solution during High Pressure Torsion of Al-Zn and Al-Mg Alloys[J]. Acta Mater., 2004, 52: 4469-4478.

[7]	Xu R. The Effect of High Pressure on Solidification Microstructure of Al-Ni-Y Alloy[J]. Mater. Lett., 2005, 59: 2818-2820.

[8]	Xu R, Zhao H, Li J, et al. Microstructures of the Eutectic and Hypereutectic Al-Ge Alloys Solidified under Different Pressures[J]. Mater. Lett., 2006, 60: 783-785.

[9]	Han B, Wu SJ. Microstructural Evolution of High Manganese Steel Solidified under Super High Pressure[J]. Mater. Lett., 2012, 70: 7-10.

[10]	Liu X, Chen JL, Tang JJ, et al. A Large Volume Cubic Press with a Pressure-Generating Capability up to about 10GPa[J]. High Press. Res., 2012, 32(2): 1-16.

[11]	Frenkel GS. Science, 1972 424

[12]	Tiller WA, Jackson KA, Rutter JW, et al. The Redistribution of Solute Atoms during the Solidification of Metals[J]. Acta Metal., 1953, 1: 428-437.

[13]	Jie JC, Zou CM, Wang HW, et al. Microstructure Evolution of Al-Mg Alloy during Solidification under High Pressure[J]. Mater. Lett., 2010, 64: 869-871.