Influence of Cooling Procedure After Transformation-Temperature-Rising on Microstructure and Property of 82B Wires
WANG Meng1,2, WANG Li-ping2, LUO Zhi-jun2, TONG Qian2, SUN Zu-qing1, LI Long-fei1
(1. State Key Laboratory of New Metals and Materials, University of Science and Technology Beijing, Beijing 100083, China 2. Shougang Research Institute of Technology, Beijing 100043, China)
Abstract:The character of microstructure and property in the segregation of 82B wire with three different stelmor control cooling procedures after tansformation-temperature-rising was researched. between 2-10 ℃/s, the cooling rate decreased to 2 ℃/s after transformation of temperature. And for 82B, the kinetics of eutectoid transformation of segregation through thermal simulation in the range of 400-600 ℃ were researched. The longitudinal section segregation microstructure and composition were analyzed by measures such as OM, SEM and EPMA. The thermal simulation results show that the length of martensite segregation bands decreased as holding time increased, and martensite band in the core of wire where the content of elements such as Mn and Cr was higher than matrix because of segregation. Furthermore, Stelmor control cooling experiments in the high speed wire mill confirms that the core of controlling martensite was slow cooling speed procedure in the post-transformation section of cooling line, while the properties of 82B will be optimized.
收稿日期: 2014-02-14
出版日期: 2014-10-13
引用本文:
王 猛 , 王丽萍, 罗志俊, 佟 倩, 孙祖庆, 李龙飞. 相变返温后冷却工艺对82B盘条组织性能的影响[J]. 钢铁, 2014, 49(10): 76-81.
WANG Meng,, WANG Li-ping, LUO Zhi-jun, TONG Qian, SUN Zu-qing, LI Long-fei. Influence of Cooling Procedure After Transformation-Temperature-Rising on Microstructure and Property of 82B Wires. Iron and Steel, 2014, 49(10): 76-81.
J.E. Stead: J. Soc. Chem. Ind., 1913, vol. 33, pp. 173–184.
[1]
J.E. Stead: J. Soc. Chem. Ind., 1913, vol. 33, pp. 173–184.
[2]
J.E. Stead: J. Iron Steel Inst., 1915, vol. 91, pp. 140–181.
[2]
J.E. Stead: J. Iron Steel Inst., 1915, vol. 91, pp. 140–181.
[3]
John D. Verhoeven. A Review of Microsegregation Induced Banding Phenomena in Steels. Journal of Materials Engineering and Performance. JMEPEG (2000) 9:286-296
[3]
John D. Verhoeven. A Review of Microsegregation Induced Banding Phenomena in Steels. Journal of Materials Engineering and Performance. JMEPEG (2000) 9:286-296
[4]
Ted F, Majka, David K, Matlock and George Krauss. Development of Microstructural Banding in Low-Alloy Steel with Simulated Mn Segregation.Metallurgical and Materials Transections A,2002,Vol.33A, p.1627-1637
[4]
Ted F, Majka, David K, Matlock and George Krauss. Development of Microstructural Banding in Low-Alloy Steel with Simulated Mn Segregation.Metallurgical and Materials Transections A,2002,Vol.33A, p.1627-1637
[5]
A.B.Sychkov,M.A.Zhigarev,S.Yu.Zhukova,A.V.Perchatkin and A.V.Peregudov. Effect of dendritic segregation in the continuous-cast semifinished product on the formation of the structure of high-carbon-steel wire rod. Metallurgist,2008,vol.52,p.275-282
[5]
A.B.Sychkov,M.A.Zhigarev,S.Yu.Zhukova,A.V.Perchatkin and A.V.Peregudov. Effect of dendritic segregation in the continuous-cast semifinished product on the formation of the structure of high-carbon-steel wire rod. Metallurgist,2008,vol.52,p.275-282
[6]
Teruo Yamashita, Shiro Torizuka and Kotobu Nagai. Effect of Manganese Segregation on Fine-grained Ferrite Structure in Low-carbon Steel Slabs. ISIJ International, 2003,Vol. 43, pp. 1833–1841.
[6]
Teruo Yamashita, Shiro Torizuka and Kotobu Nagai. Effect of Manganese Segregation on Fine-grained Ferrite Structure in Low-carbon Steel Slabs. ISIJ International, 2003,Vol. 43, pp. 1833–1841.
[7]
S.W. Thompson and P.R. Howell.Mater. Sci. Technol., 1992, vol. 8, pp. 777-784.
[7]
S.W. Thompson and P.R. Howell.Mater. Sci. Technol., 1992, vol. 8, pp. 777-784.
[8]
L.E. Samuels.Optical Microscopy of Carbon Steels, Asm International, Metals Park, OH, 1980, pp. 127-128.
[8]
L.E. Samuels.Optical Microscopy of Carbon Steels, Asm International, Metals Park, OH, 1980, pp. 127-128.