Authors: Hyun-Ho Kim, Seok-Jae Lee, Oh-Yeon Lee

Abstract:

We investigated the effects of the additions of Zr and other alloying elements on the mechanical properties and microstructure in Cr-Mo plastic mold steels. The addition of alloying elements changed the microstructure of the normalized samples from the upper bainite to lower bainite due to the increased hardenability. The tempering temperature influenced the strength and hardness values, especially the phenomenon of 350^oC embrittlement was observed. The alloy additions of Cr, Mo, and V improved the resistance to the temper embrittlement. The addition of Zr improved the tensile strength and yield strength, but the impact energy was sharply decreased. It may be caused by the formation of Zr-MnS inclusion and rectangular-shaped Zr inclusion due to the Zr addition.

Keywords: Inclusions, mechanical properties, plastic mold steel, Zr addition.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1088428

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References:

[1] K. Narita, Y. Yamaguchi, N. Yagi, and T. Shimohata, “Resulphurized steels containing zirconium,” Tetsu-to-hagané, vol. 62, pp. 885–894, 1976.
[2] T. Sawai, M. Wakoh, and S. Mizoguchi, “Effect of Zr-oxide particles on the MnS precipitation in low S steels,” Tetsu-to-hagané, vol. 82, pp. 587–592, 1996.
[3] M. Wakoh, T. Sawai, and S. Mizoguchi, “Effect of Ti-Zr oxide particles on MnS precipitation in low S steels,” Tetsu-to-hagané, vol. 82, pp. 593–598, 1996.
[4] H. Hasegawa, K. Nakajima, and S. Mizoguchi, “The effects of inclusions in steel on MnS precipitation in Fe-Si alloys,” Tetsu-to-hagané, vol. 87, pp. 700–706, 2001.
[5] K. Kato, “On the deformation of sulfides in high-sulphur steels by working and the effect of Zr addition,” Tetsu-to-hagané, vol. 48, pp. 753–761, 1962.
[6] Z. Tang and W. Strumpf, “The role of molybdenum additions and prior deformation on acicular ferrite formation in microalloyedNb-Ti low-carbon line-pipe steels,” Mater. Charac., vol. 59, pp. 717–728, 2008.
[7] M. Honjo and Y. Saito, “Numerical simulation of phase separation in Fe-Cr binary and Fe-Cr-Mo ternary alloys with use of the Cahn-Hilliard equation,” ISIJ Inter., vol. 40, pp. 914–919, 2000.
[8] B.S. Lement, B.L. Averbach, and M. Cohen, “Microstructural changes on tempering iron-carbon alloys,” Trans. ASM, vol. 46, pp. 851–881, 1954.
[9] C.J. Altstetter, M. Cohen, and L. Averbach, “Effect of silicon on the tempering of AISI 43XX steels,” Trans. ASM, vol. 55, pp. 287–300, 1962.
[10] G. Thomas, “Retained austenite and tempered martensiteembrittlement,” Metall. Trans., vol. 9, pp. 439–450, 1978.
[11] J.P. Materkowski and G. Krauss, “Tempered martensiteembrittlement in SAE 4340 steel,” Metall. Trans., vol. 10, pp. 1643–1651, 1979.
[12] R.M. Horn and R.O. Ritchi, “ Mechanisms of tempered martensiteembrittlement in low alloy steels,” Metall. Trans., vol. 9, pp. 1039–1053, 1978.
[13] C.L. Braiant and S.K. Banerji, “Phosphorus induced 350o C embrittlement in an ultra-high strength steel,” Metall. Trans., vol. 10, pp. 123–126, 1979.
[14] C.L. Braiant and S.K. Banerji, “Tempered martensiteembrittlement in phosphorus doped steels,” Metall. Trans., vol. 10, pp.1729–1737, 1979.
[15] C.L. Braiant and S.K. Banerji, “Tempered martensiteembrittlement in a high purity steel,” Metall. Trans., vol. 10, pp. 1151–1155, 1979.
[16] H. Takada, K, Kaneco, T. Inoue, and S. Kinoshita, “Effect of shape of MnS inclusion on ductility of rolled plate,” Tetsu-to-hagané, vol. 62, pp. 866–874, 1976.