| METALS AND METAL MATRIX COMPOSITES |
|
|
|
|
|
| Study on Residual Stress of High-strength Structural Steel Plate Under Different States Based on Ultrasonic Method |
| FU Tongyu1,2, CAO Yanguang2, LI Zhaodong2, WEI Kunxia1,*, ZHANG Jianwei3, TAN Fengliang4
|
1 Jiangsu Provincial Key Laboratory of Materials Surface Science and Technology, Key Laboratory of Equipment Surface Engineering and New Materials for Petroleum and Chemical Industry, Changzhou University, Changzhou 213164, Jiangsu, China
2 Institute of Structural Steels, Central Iron and Steel Research Institute, Beijing 100081, China
3 NCS Testing Technology Co., Ltd., Beijing 100081, China
4 School of Materials and Environmental Engineering, Hunan University of Humanities and Technology, Loudi 417000, Hunan, China |
|
|
|
|
Abstract With the wide application of high strength structural steel plate in engineering field, the detection and control of residual stress is of great significance to the production and application of steel plate and its components. In this work, the influence of straightening and annealing treatment on the residual stress of high strength steel plate was studied based on ultrasonic method, and the internal relationship between the microstructure and the residual stress was analyzed. The results show that the residual stress of 700 MPa steel plate in hot rolling state is large and uneven. The residual stress in rolling direction ranges from -26 MPa to 232 MPa, and the residual stress in transverse direction ranges from -562 MPa to -141 MPa. After straightening, the rolling direction and lateral residual stress of the steel plate are improved compared with the hot rolled state. The difference between the maximum and minimum rolling direction and lateral residual stress is 168 MPa and 351 MPa, which is reduced by 34.88% and 16.62%, because straightening improves the uniformity of stress distribution. The plastic deformation of the steel plate occurs under the condition of small tension, and the crystal slip promotes the rotation of grain orientation, which is conducive to the continuous increase of orientation density, and the dislocation slip is easier to occur, so that the residual stress can be released and redistributed. After stress-relieving heat treatment, compared with straightened state, the difference between the maximum and minimum residual stresses in rolling direction and transverse direction is 79 MPa and 228 MPa, decreasing by 52.98% and 35.04%. This is due to the effect of thermal activation, dislocation obligation and rearrangement occur inside the crystal, which effectively improves the large number of disordered dislocations generated during the processing. The residual stress and distribution of the steel plate are improved.
|
|
Published:
Online: 2025-08-28
|
|
|
|
|
1 Yin B S, Zhao H P, Wang X H. Physical and Chemical Inspection (Physics Branch), 2007(12), 642(in Chinese).
印兵胜, 赵怀普, 王晓洪. 理化检验(物理分册), 2007(12), 642.
2 Tabatabaeian A, Ghasemi A R, Shokrieh M M, et al. Advanced Engineering Materials, 2022, 24(3), 2100786.
3 Song W T. Research on ultrasonic nondestructive testing and control technology of residual stress. Ph. D. Thesis, Beijing Institute of Technology, 2016 (in Chinese).
宋文涛. 残余应力超声无损检测与调控技术研究. 博士学位论文, 北京理工大学, 2016.
4 Song J, Xu C, Li Z. IOP Conference Series:Materials Science and Engineering, 2018, 397(1), 012136.
5 de Araújo Freitas V L, de Albuquerque V H C, de Macedo Silva E, et al. Materials Science and Engineering:A, 2010, 527(16-17), 4431.
6 Ambardar R, Muthu M T, Pathak S D, et al. Insight, 1995, 37(7), 536.
7 Cui D, He X P, Liu X R, et al. Journal of Shaanxi Normal University:Natural Science Edition, 2016, 44(1), 24(in Chinese).
崔东, 贺西平, 刘小荣, 等. 陕西师范大学学报:自然科学版, 2016, 44(1), 24.
8 Hirao M, Aoki K, Fukuoka H. Journal of the Acoustical Society of America, 1987, 81(5), 1434.
9 Ahmed S, Thompson R B. Review of Progress in Quantitative Nondestructive Evaluation, 1992, 11, 1999.
10 Rose J L. Ultrasonic guided waves in solid media, Cambridge University Press, US, 2014, pp. 36.
11 Karabutov A, Devichensky A, Ivochkin A, et al. Ultrasonics, 2008, 48(6), 631.
12 Castellano A, Fraddosio A, Marzano S, et al. Procedia Engineering, 2017, 199, 1519.
13 Wang T Z, Li Y, Dong Z, et al. Journal of Materials Engineering, 2023, 51(7), 33(in Chinese).
王天政, 李洋, 董哲, 等. 材料工程, 2023, 51 (7), 33.
14 Liu J L, Li Z D, Cao Y G, et al. Materials Engineering, DOI:10.11868/j.issn.1001-4381.2022.000984(in Chinese).
刘佳磊, 李昭东, 曹燕光, 等. 材料工程, DOI:10.11868/j.issn.1001-4381.2022.000984.
15 He L F, Liu J. Acoustic elasticity technology, Science Press, China, 2002, pp. 107 (in Chinese).
贺玲凤, 刘军. 声弹性技术, 科学出版社, 2002, pp. 107.
16 Shi Y W. Ultrasonic testing, China Machine Press, China, 2005, pp. 31 (in Chinese).
史亦伟. 超声波检测, 机械工业出版社, 2005, pp. 31.
17 Meng Y Y, Lin L, Chen J, et al. Journal of Materials Engineering, 2022, 50(10), 172(in Chinese).
孟亦圆, 林莉, 陈军, 等. 材料工程, 2022, 50(10), 172.
18 Xu C G, Li W B. Fundamentals of Ultrasonic Testing, Science Press, China, 2021, pp. 317 (in Chinese).
徐春广, 李卫彬. 无损检测超声波理论, 科学出版社, 2021, pp. 317.
19 Wang W, Rokhlin S I, Lippold J C, et al. Materials Evaluation, 1989, 47(12), 1388.
20 Han F X, Sun X P, Lou M Q, et al. Titanium Industry Progress, 2023, 40(6), 16(in Chinese).
韩飞孝, 孙小平, 楼美琪, 等. 钛工业进展, 2023, 40(6), 16.
21 Lean J T, Hameed T M S, Andrzej Ł, et al. Materials (Basel, Switzerland), 2023, 16(14), 5123.
22 Wackenrohr S, Herbst S, Wöbbeking P, et al. Journal of Manufacturing and Materials Processing, 2023, 7(4), 142.
23 Sravya T, Matteo S, Stefan Z. Acta Materialia, 2024, 262, 119413.
24 Zhu J H, Wei L L, Huang H F, et al. Journal of Materials Engineering, 2023, 5(10), 76(in Chinese).
朱家豪, 韦莉莉, 黄宏锋, 等. 材料工程, 2023, 5(10), 76.
25 Li S G. Post-processing of C19400 strip organizational performance and the influence of residual stress. Master's Thesis, Henan University of Science and Technology, China, 2022 (in Chinese).
李闪光. 后处理对C19400带材组织性能与残余应力的影响. 硕士学位论文, 河南科技大学, 2022.
26 Yang X, Fu B, Han J, et al. Journal of Materials Engineering, 2023, 51(11), 189(in Chinese).
杨旭, 傅斌, 韩洁, 等. 材料工程, 2023, 51(11), 189.
27 Li H, Li Z D, Cao J, et al. Journal of Materials Engineering, 2023, 51(9), 117(in Chinese).
李涵, 李昭东, 曹杰, 等. 材料工程, 2023, 51(9), 117.
28 Gao J M, Huang H, Shi W, et al. Journal of Materials Engineering, 2022, 50(11), 101(in Chinese).
高杰明, 黄晖, 石薇, 等. 材料工程, 2022, 50(11), 101. |
|
|
|
渝公网安备50019002502923号 © Editorial Office of Materials Reports.
2025, Vol. 39 
