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EFFECT OF DEFORMATION TEMPERATURE ON TENSILE DEFORMATION MECHANISM OF Fe-23Mn-2Al-0.2C TWIP STEEL |
QIN Xiaomei, CHEN Liqing, DI Hongshuang, DENG Wei |
State Key Laboratory of Rolling and Automation, Northeastern University, Shenyang 110819 |
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Cite this article:
QIN Xiaomei CHEN Liqing DI Hongshuang DENG Wei. EFFECT OF DEFORMATION TEMPERATURE ON TENSILE DEFORMATION MECHANISM OF Fe-23Mn-2Al-0.2C TWIP STEEL. Acta Metall Sin, 2011, 47(9): 1117-1122.
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Abstract Twinning-induced plasticity (TWIP) steel can be classified into three types, Fe-Mn-Al-Si, Fe-Mn-C and Fe-Mn-Al-C steels. Owing to their high strength, superior plasticity and good formability, they have potential applications in automobile manufacturing industry as a new generation of steels. In order to reveal the dependence of deformation mechanism on temperature for Fe-23Mn-2Al-0.2C TWIP steel, microstructural observation, stacking fault energy calculation and tensile deformation experiments were performed at a temperature range from -60 ℃ to 600 ℃. With increasing the deformation temperature, the strength and elongation to failure of this steel firstly decrease, then increase and finally decrease. And their peak values appear at 300 ℃ during high temperature deformation. As deformation temperature increased from -60 ℃ to 600℃, the stacking fault energy of the steel increases and the deformation mechanism is changed from twining to slipping. Deformation twins with high density appear at lower deformation temperatures, however, they will gradually decrease with increasing temperature. When the sample was deformed at 600 ℃, only dislocations and dislocation cells appear. High-density deformation twins formed during low-temperature deformation result in the high tensile strength and elongation to failure in this steel.
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Received: 07 April 2011
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Fund: Supported by National Basic Research Program of China (No.2011CB606306-2) and Fundamental Research Funds for the Central Universities (No.N100507003) |
[1] Allain S, Chateau J P, Bouaziz O, Migot S, Guelton N. Mater Sci Eng, 2004; A387–389: 158[2] Frommeyer G, Br¨ux U, Neumann P. ISIJ Int, 2003; 43: 438[3] Hokka M, Kuokkala V T, Curtze S, Vuoristo T, Apostol M. J Phy IV, 2006; 134: 1301[4] Gr¨assel O, Kr¨uger L, Frommeyer G, Meyer L W. Int J Plast, 2000; 16: 1391[5] Wang S H, Liu Z Y, Wang G D. Acta Metall Sin, 2009; 45: 1083(王书晗, 刘振宇, 王国栋. 金属学报, 2009; 45: 1083)[6] Hamada A S, Karjalainen L P, Somani M C. Mater Sci Eng, 2007; A467: 114[7] Huang B X, Wang X D, Wang L, Rong Y H. Metall Mater Trans, 2008; 39A: 717[8] Lu F Y, Yang P, Meng L, Mao W M. Acta Metall Sin, 2010; 46: 1153(鲁法云, 杨平, 孟 利, 毛卫民. 金属学报, 2010; 46: 1153)[9] Barbier D, Gey N, Allain S, Bozzolo N, Humbert M. Mater Sci Eng, 2009; A500: 196[10] Chen L, Kim H S, Kim S K, Cooman B C. ISIJ Int, 2007; 47: 1804[11] Jim´enez J A, Frommeyer G. Mater Charact, 2010; 61: 221[12] Renard K, Ryelandt S, Jacquies P J. Mater Sci Eng, 2010; A527: 2969[13] Brahmi A, Borrelly R. Acta Mater, 1997; 45: 1889[14] Frommeyer G, Brux U. Steel Res Int, 2006; 77: 627[15] Yoo J D, Park K T. Mater Sci Eng, 2008; A496: 417[16] Dumay A, Chateau J P, Allain S, Migot S, Bouaziz O. Mater Sci Eng, 2008; A483–484: 184[17] Ehab E D, Surya R K, Roger D D. Metall Mater Trans, 1999; 30A: 1223[18] Surya R K. Int J Plast, 1998; 14: 1265 |
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