MECHANICAL PROPERTIES OF CONTINUOUSLY ANNEALLED Si–FREE P–CONTAINING TRIP STEEL

doi:10.3724/SP.J.1037.2011.00152

Acta Metall Sin

2011, Vol. 47

Issue (8): 1022-1025 DOI: 10.3724/SP.J.1037.2011.00152

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MECHANICAL PROPERTIES OF CONTINUOUSLY ANNEALLED Si–FREE P–CONTAINING TRIP STEEL

DING Wei ^1,2, TANG Di ², JIANG Haitao ², WANG Baofeng ^1,3, GONG Zhihua ¹

1. School of Material and Metallurgy, Inner Mongolia University of Science and Technology, Baotou 014010
2. National Engineering Research Center for Advanced Rolling Technology, University of Science & Technology, Beijing 100083
3. International School, Inner Mongolia University of Science and Technology, Baotou 014010

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DING Wei TANG Di JIANG Haitao WANG Baofeng GONG Zhihua. MECHANICAL PROPERTIES OF CONTINUOUSLY ANNEALLED Si–FREE P–CONTAINING TRIP STEEL. Acta Metall Sin, 2011, 47(8): 1022-1025.

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Abstract Since its advent, TRIP steel has been considered as the best automotive steel to improve the automotive safety dramatically because of its excellent mechanical properties. However, TRIP steel was not widely used and the main reason is that the large amount of Si in the steel led to surface quality problems of the plate. In this work a kind of C–Mn–Al–P TRIP steel with Si being replaced by Al and P was designed and subjected to continuous annealing. The macro and micro mechanical performance was analyzed. The results showed that the mechanical properties were excellent with tensile strength between 740 and 790 MPa and elongation above 25%, indicating that the production of TRIP steel without Si addition was feasible. Compared with traditional TRIP steel with Si, the designed steel demonstrated higher yield strength of 550—600 MPa, which was a little higher than that of high Si steel and much higher than that of medium or low Si steel. The micro hardness of ferrite was measured by nano mechanics probe and it was 0.6 GPa higher than that of medium Si TRIP steel. The IF steel whose strength was already known was used as a calibration and the conclusion was that the 0.6 GPa difference in nano hardness could result in 75 MPa difference in yield strength and 80 MPa division in tensile strength. Through further analysis, it was believed that the higher strength of ferrite was mainly caucsed by C, not P.

Key words: non–Si TRIP steel mechanical property

Received: 23 March 2011

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Supported by National Natural Science Foundation of China (No.50804005)

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https://www.ams.org.cn/EN/10.3724/SP.J.1037.2011.00152 OR https://www.ams.org.cn/EN/Y2011/V47/I8/1022

[1] Zackay F, Parker E R, Fahr D, Bush R. ASM Trans Quart, 1967; 60: 252

[2] Sakuma Y, Matsumura O, Takechi H. Metall Mater Trans, 1991; 22A: 489

[3] Sugimoto K, Usui N, Kobayashi M, Hashimoto S. ISIJ Int, 1992; 32: 1311

[4] Bhadeshia H K D H, Edmonds D V. Metall Mater Trans, 1979; 10A: 895

[5] Takahashi M , Bhadeshia H K D H. Mater Trans JIM, 1991; 32: 689

[6] Meyer M D, Vanderschueren D, de Cooman B C. ISIJ Int, 1999; 39: 813

[7] Jacques P J, Girault E, Mertens A, Verlinden B, Humbeeck J V, Delannay F. ISIJ Int, 2001; 41: 1068

[8] Suh D, Park S, Oh C, Kim S. Scr Mater, 2007; 57: 1097

[9] Srivastava A K, Bhattacharjee D, Jha G, Gope N, Singh S B. Mater Sci Eng, 2007; A445–446: 549

[10] Mahieu J, Maki J, De Cooman B C, Claessens S. Metall Mater Trans, 2002; 33A:2573

[11] Chen H C, Era H, Shimizu M. Metall Mater Trans, 1989; 20A: 437

[12] Jing C, Suh D, Oh C, Wang Z, Kim S. Met Mater Int, 2007; 13: 13

[13] Li L, De Cooman B C, Liu R, Vleugels J, Zhang M, Shi W. J Iron Steel Res Int, 2007; 14(6): 37

[14] Barb´e L, Verbeken K, Wettinck E. ISIJ Int, 2006; 46: 1251

[15] Zhou Y, Wu G H. Analysis Methods in Materials Science. Harbin: Harbin Institute Technology Press, 2007: 95

(周玉, 武高辉. 材料分析测试技术. 哈尔滨: 哈尔滨工业大学出版社, 2007: 95)

[16] Liu Q, Tang D, Jiang H T, Liu R D, Tang X Y. Int J Min Met Mater, 2009; 16: 399

[17] MaM T,Wu B R. Dual–Phase Steel–Physics and Mechanics Metallurgy, 2nd ed., Beijing: Metallurgical Industry Press, 2009: 1

(马鸣图, 吴宝榕. 双相钢---物理和力学冶金(第二版). 北京: 冶金工业出版社, 2009: 1)

[18] Ding W, Tang D, Jiang H T, Huang W. Acta Metall Sin, 2010; 46: 595

(定巍, 唐荻, 江海涛, 黄伟. 金属学报, 2010; 46: 595)

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