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Austenite transformation and work hardening of medium manganese steel |
Lei Zhang1,2,3 . Cun-yu Wang2 . Heng-chang Lu2 . Wen-quan Cao2 . Chang Wang2 . Han Dong2 . Leng Chen1 |
1 School of Materials Science and Engineering, University of Science and Technology Beijing, Beijing 100083, China 2 Special Steel Institute of Central Iron and Steel Research Institute, Beijing 100081, China 3 Mechanical Engineering Department of Tangshan Polytechnic College, Tangshan 063299, Hebei, China |
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Abstract The austenite transformation behavior and mechanical properties of medium manganese steel subjected to tensile strain were studied by electron backscatter diffraction, X-ray diffraction and tensile tests. The results show that the austenite phases are mainly distributed on the grain boundary in the duplex microstructure of austenite and ferrite, and it is easy for the big-size austenite to transform at small beginning tension strain following the mechanisms of both austenite (fcc) → ε-martensite (hcp) → α-martensite (bcc) and austenite (fcc) → α-martensite (bcc). Both yield strength and tensile strength increase with the increase in pre-strain, and the total elongation decreases, while the value of pre-strain plus total elongation almost keeps constant. During tensile deformation, transformation from austenite into martensite improves work-hardening rate remarkably.
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Received: 20 September 2017
Published: 23 January 2019
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Cite this article: |
ZHANG,YU Cun-Yu,LU Heng-Chang, et al. Austenite transformation and work hardening of medium manganese steel[J]. Journal of Iron and Steel Research International, 2018, 25(12): 1265-1269.
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[1] |
S. Oliver, T.B. Jones, G. Fourlaris, Mater. Charact., 58 (2007) 390-400.
|
[2] |
A. Saha Podder, D. Bhattacharjee, R. K. Ray. ISIJ Int., 47 (2007) 1058-1064.
|
[3] |
R.H. Wagoner, Report: Advanced High-Strength Steel Workshop, Arlington, Virginaia, USA, October 22–23, 2006.
|
[4] |
D.K. Matlock, J.G. Speer, Proc.3rd Inter. Conf on Advanced Structural Steels, 2006, 774–781.
|
[5] |
O. Kwon, S.K. Kim, G. Kim, Proceedings of the 21st Conference on Mechanical Behaviors of Materials, Changwon, Korea, October 18–19, 2007.
|
[6] |
H.N. Han, C.S. Oh, G. Kim, O. Kwon, Mater. Sci. Eng. A, 499 (2009) 462–468.
|
[7] |
K. Sugimoto, B. Yu, Y. Mukai, S. Ikeda, ISIJ 45 (2005) 1194–1200.
|
[8] |
G. Frommeyer, U. Brux, P. Neumann, ISIJ 43 (2003) 438–446.
|
[9] |
J. Han, S.J. Lee, C.J. Lee, S. Lee, S.Y. Jo, Y.J. Lee, Mater. Sci. Eng. A 633 (2015) 9–16.
|
[10] |
K.T. Park, Scripta Mater. 68 (2013) 337–338.
|
[11] |
L.A. Dobrzanski, W. Borek, J. Achiev, Mater. Manuf. Eng. 55 (2012) 230–238.
|
[12] |
W.S. Li, H.Y. Gao, H. Nakashima, Mater. Sci. Eng. A, 649 (2016) 417-425.
|
[13] |
H.J. Hu, A.M. Zhao, Z.K. Yin, Transaction of Materials and Heat Treatment, 37 (5) (2016) 128-132(in chinese).
|
[14] |
C.H. Song, H. Yu, L.L. Li, Mater. Sci. Eng. A, 670 (2016) 326–334
|
[15] |
Y. Zhou, Material Analysis Method. 2006, China Machine Press(in chinese).
|
[16] |
C. Wang, J. Shi, C. Y. Wang, ISIJ Int, 2011,51(4):651–656.
|
[17] |
H. B. Jiang, X. N. Luo, X. Y. Zhong, J. of Iron and Steel Res(acceptable).
|
[18] |
J. Lin,X N. Luo,X. Y. Zhong,H. H. Zhou, J. of Iron and Steel Res.2016, 23(12):1277-1280.
|
[19] |
E. Jimenez-Melero, N.H. van Dijk, L. Zhao, Scripta. Mater. 56 (5) (2007) 421–424.
|
[20] |
F.Y. Lu, P. Yang, L. Meng, Acta Metall. 46 (10) (2010) 1153-1160.
|
[21] |
P. Yang, F.Y. Lu, L. Meng, Acta Metall. 46 (6) (2010) 657-665.
|
[22] |
S. Liu, Z. Xiong, H. Guo, Acta Mater, 124 (2017) 159-172.
|
[23] |
C. Wang, Diploma Thesis, Central Iron & Steel Research Institute, 2016.
|
[24] |
D.T. Jiao, Q.W. Cai,H. B. Wu, Acta Metall, 45 (9) (2009) 1111-1116.
|
[25] |
W.X. Song. Physical Metallergy.1980, Metallurgical Industry Press(in chinese).
|
[26] |
W.F. Zhang, Y.M. Chen, J.H. Zhu, J. of Xi′an Jiao Tong University, 33 (10) (1999) 64-67.
|
[27] |
Z.H. Cai, Q.B. Xin, H. Kong, J. of Northeastern University (Natural Science), 34(12) (2013) 1721-1729.
|
[28] |
C. Wang, W.Q. Cao, J. Shi, Mater. Sci. Eng. A, 2013,562:89-95
|
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