Effect of hot rolling on the microstructure and impact absorbed energy of the strip steel by CSP

被引:0
作者
Yang, Jing-jing [1 ,2 ]
Wu, Run [1 ,2 ]
Liang, Wen [3 ]
Xiang, Zhi-dong [1 ]
Tang, Meng-xia [1 ]
机构
[1] Wuhan Univ Sci & Technol, State Key Lab Refractories & Met, Wuhan 430081, Peoples R China
[2] Wuhan Univ Sci & Technol, Key Lab Ferrous Met & Resources Utilizat, Minist Educ, Wuhan 430081, Peoples R China
[3] Wuhan Iron & Steel Corp, Res & Design Inst, Wuhan 430080, Peoples R China
来源
INTERNATIONAL JOURNAL OF MINERALS METALLURGY AND MATERIALS | 2014年 / 21卷 / 07期
关键词
strip steel; hot rolling; tensile properties; Charpy impact testing; precipitates; ULTRAFINE-GRAINED METALS; FRACTURE-TOUGHNESS; NANOSTRUCTURED MATERIALS; MICROALLOYED STEEL; DUCTILITY; TEMPERATURE; STRENGTH; NANOCRYSTALLINE; ALLOYS; SIZE;
D O I
10.1007/s12613-014-0957-y
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
The microstructures and impact absorbed energies at various temperatures were investigated for steel strips hot rolled to thickness reductions of 95.5%, 96.0%, 96.5%, 97.0%, and 97.5%. Results indicate that grain refinement can be realized with an increase in hot rolling reduction. Besides, finer precipitates can be achieved with an increase in hot rolling reduction from 95.5% to 97.0%. The impact absorbed energy decreases with a decrease in testing temperature for steel strips hot rolled to 95.5%, 96.0%, and 96.5% reductions in thickness. However, in the case of steel strips hot rolled to 97.0% and 97.5% reductions in thickness, the impact absorbed energy remained almost constant with a decrease in testing temperature.
引用
收藏
页码:674 / 681
页数:8
相关论文
共 23 条
[1]   Failure assessment diagrams for high temperature defect assessment [J].
Ainsworth, RA ;
Hooton, DG ;
Green, D .
ENGINEERING FRACTURE MECHANICS, 1999, 62 (01) :95-109
[2]   Charpy impact energy, fracture toughness and ductile-brittle transition temperature of dual-phase 590 steel [J].
Chao, Y. J. ;
Ward, J. D., Jr. ;
Sands, R. G. .
MATERIALS & DESIGN, 2007, 28 (02) :551-557
[3]   Optimizing the strength and ductility of fine structured 2024 Al alloy by nano-precipitation [J].
Cheng, S. ;
Zhao, Y. H. ;
Zhu, Y. T. ;
Ma, E. .
ACTA MATERIALIA, 2007, 55 (17) :5822-5832
[4]   FRACTAL FRACTURE-MECHANICS - A REVIEW [J].
CHEREPANOV, GP ;
BALANKIN, AS ;
IVANOVA, VS .
ENGINEERING FRACTURE MECHANICS, 1995, 51 (06) :997-1033
[5]   Assessment of local thin areas in a marine pipeline by using the FITNET FFS corrosion module [J].
Cicero, S. ;
Lacalle, R. ;
Cicero, R. ;
Ferreno, D. .
INTERNATIONAL JOURNAL OF PRESSURE VESSELS AND PIPING, 2009, 86 (05) :329-334
[6]   The mechanism of brittle fracture in a microalloyed steel: Part I. Inclusion-induced cleavage [J].
Fairchild, DP ;
Howden, DG ;
Clark, WAT .
METALLURGICAL AND MATERIALS TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE, 2000, 31 (03) :641-652
[7]   Effective grain size and charpy impact properties of high-toughness X70 pipeline steels [J].
Hwang, B ;
Kim, YG ;
Lee, S ;
Kim, YM ;
Kim, NJ ;
Yoo, JY .
METALLURGICAL AND MATERIALS TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE, 2005, 36A (08) :2107-2114
[8]   Small specimen test technique for evaluating fracture toughness of blanket structural materials [J].
Kasada, R ;
Ono, H ;
Kimura, A .
FUSION ENGINEERING AND DESIGN, 2006, 81 (8-14) :981-986
[9]   Ductility of nanostructured materials [J].
Koch, CC ;
Morris, DG ;
Lu, K ;
Inoue, A .
MRS BULLETIN, 1999, 24 (02) :54-58
[10]   Optimization of strength and ductility in nanocrystalline and ultrafine grained metals [J].
Koch, CC .
SCRIPTA MATERIALIA, 2003, 49 (07) :657-662
123