600 MPa GRADE REBAR WITH HIGH DUCTILITY DEVELOPED BASED ON THEORY OF YIELD PLATEAU

doi:10.3724/SP.J.1037.2013.00768

Acta Metall Sin

2014, Vol. 50

Issue (4): 439-446 DOI: 10.3724/SP.J.1037.2013.00768

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600 MPa GRADE REBAR WITH HIGH DUCTILITY DEVELOPED BASED ON THEORY OF YIELD PLATEAU

LI Xiaolong¹, GUO Zhenghong¹(

), RONG Yonghua¹, WU Haiyang², YAO Shengfa²

1 School of Materials Science and Engineering, Shanghai Jiao Tong University, Shanghai 200240
2 Tianshun Group of Jiangsu, Yangzhong 212200

Cite this article:

LI Xiaolong, GUO Zhenghong, RONG Yonghua, WU Haiyang, YAO Shengfa. 600 MPa GRADE REBAR WITH HIGH DUCTILITY DEVELOPED BASED ON THEORY OF YIELD PLATEAU. Acta Metall Sin, 2014, 50(4): 439-446.

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Abstract

Development of high strength and high ductility rebar with obvious yield plateau is a tendency for anti-seismic requirement in building steels. In this work, the basic relationship between ferrite grain size and mechanical property, especially the elongation of yield plateau, was investigated by the combination of cold-rolling and heat treatment. After several passes of cold rolling followed by recrystallization annealing for 5~300 min at 600 ℃, ferrite with grain size between 5.2~40.4 μm was obtained in plain steel plates with a carbon content of 0.1%(mass fraction). Mechanical properties were studied by tensile test. With the decrease of ferrite grain size, not only the strength but also the elongation of yield plateau increases. Base on the scanning electron microscopy observation, the deformation becomes more homogeneous with the decrease of grain size, resulting in a higher elongation of yield plateau. A quantitative relationship between grain size d_α and the elongation of yield plateau δ_L was derived from the combination of Hollomon and Hall-Petch equations. The application range of d_α-δ_L equation was also determined, which is well consistent with the experimental results. The narrow-slit spraying equipment was used to treat the HRB400 rebar, and refined ferrite and a considerable non-equilibrium pearlite were obtained due to high cooling rate in treatment. A novel rebar with yield strength of 600 MPa grade was manufactured successfully in commerce, which also verified the above theoretical analysis.

Key words: 600 MPa grade rebar grain refinement strengthening elongation of yield plateau

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	Xiaolong LI
	Zhenghong GUO
	Yonghua RONG
	Haiyang WU
	Shengfa YAO

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https://www.ams.org.cn/EN/10.3724/SP.J.1037.2013.00768 OR https://www.ams.org.cn/EN/Y2014/V50/I4/439

[1]	Bannister A C. Contribution to Sub-Task 2.3: Assessment of the Occurrence and Significance of Yield Plateaus in Structural Steels. Report No.SINTAP/BS/19, Brite-Euram BE 95-1426, Rotherham: British Steel Plc, 1998: 7
[2]	Kot R A, Morris J W. Structure and Properties of Dual-Phase Steels. New York: The Metallurgical Society of AIME, 1979: 304
[3]	Kumar A, Singh S B, Ray K K. Mater Sci Eng, 2008; A474: 270
[4]	Cottrell A H, Bilby B A. Proc Phys Soc, 1949; 62A: 49
[5]	Hale K F, McLean D. J Iron Steel Inst, 1963; 201: 337
[6]	Tekin E, Kelly P M. J Iron Steel Inst, 1965; 203: 715
[7]	Dollins C, Wert C. Acta Metall, 1969; 17: 711
[8]	Cottrell A H, Stokes R J. Proc Roy Soc, 1955; 233A: 17
[9]	Tsuchida N, Tomota Y, Nagai K, Fukaura K. Scr Mater, 2006; 54: 57
[10]	Fujita H, Miyazaki S. Acta Metall, 1978; 26: 1273
[11]	Schulson E M, Weihs T P, Viens D V, Baker I. Acta Metall, 1985; 33: 1587
[12]	Hall E O. Yield Point Phenomena in Metals and Alloys. London: Macmillan, 1970: 31
[13]	Hall E O. Proc Phys Soc London, 1951; 64B: 747
[14]	Petch N J. J Iron Steel Inst, 1953; 174: 25
[15]	Wen C S, Rong Y H, Xu Z Y. Trans Mater Heat Treat, 2004; 25: 161
[16]	Tsuji N, Ito Y, Saito Y, Minamino Y. Scr Mater, 2002; 47: 893
[17]	Takaki S, Kawasaki K, Kimura Y. J Mater Proc Technol, 2001; 117: 359
[18]	Song R, Ponge D, Raabe D. Acta Mater, 2005; 53: 4881
[19]	Tsuji N, Kamikawa N, Ueji R, Takata N, Koyama H, Terada D. ISIJ Int, 2008; 48: 1114
[20]	Tsuchida N, Masuda H, Harada Y, Fukaura K, Tomota Y, Nagai K. Mater Sci Eng, 2008; A488: 446
[21]	Zhao M, Yin F, Hanamura T, Nagai K, Atrens A. Scr Mater, 2007; 57: 857
[22]	Miller R L. Metall Trans, 1972; 3: 905
[23]	Shu D L. Mechanical Property of Engineering Materials. Beijing: Mechanical Industry Press, 2003: 19
	(束德林. 工程材料力学性能. 北京: 机械工业出版社, 2003: 19)
[24]	Schwarb R, Ruff V. Acta Mater, 2013; 61: 1798
[25]	Hu G X,Cai X,Rong Y H. Fundamentals of Materials Science. 2nd Ed., Shanghai: Shanghai Jiao Tong University Press, 2006: 180
	(胡赓祥,蔡珣,戎咏华. 材料科学基础. 第二版, 上海: 上海交通大学出版社, 2006: 180)
[26]	Chen N L, Rong Y H, Zuo X W, Guo Z H. Chin Pat, ZL 2011 1 0453958.2, 2013
	(陈乃录, 戎咏华, 左训伟, 郭正洪. 中国专利, ZL 2011 1 0453958.2, 2013)

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