|
|
Strengthening and toughening mechanism of a Cu-bearing highstrength low-alloy steel with refined tempered martensite/bainite (M/ B) matrix and minor inter-critical ferrite |
Fei Zhu1, Feng Chai1, Xiao-bing Luo1, Zheng-yan Zhang1, Cai-fu Yang1 |
1 Department of Structural Steels, Central Iron and Steel Research Institute, Beijing 100081, China |
|
|
Abstract The microstructure–mechanical property relationship of a Cu-bearing low-carbon high-strength low-alloy steel, subjected to a novel multistage heat treatment including quenching (Q), lamellarization (L) and tempering (T), is presented. Yield strength of 989.5 MPa and average toughness at - 80 °C of 41 J were obtained in this steel after quenching and tempering (QT) heat treatments. Specimen QLT gained a little lower yield strength (982.5 MPa), but greatly enhanced average toughness at - 80 °C (137 J). To further clarify the strengthening and toughening mechanisms in specimen QLT, parameters of microstructural characteristic and crack propagation process were compared and analyzed for specimens Q, QL, QT and QLT. The microstructure of tempered martensite/bainite (M/B) in specimen QT changed to refined tempered M/B matrix mixed with minor IF (inter-critical ferrite) in specimen QLT. Cu-rich precipitates existed in tempered M/B for both specimens QT and QLT, as well as in IF. Compared with QT, adding a lamellarization step before tempering made the effective grains of specimen QLT refined and also led to coarser Cu-rich precipitates in tempered M/B matrix. The weaker strengthening effect of coarser Cu-rich precipitates should be a key reason for the slightly lower yield strength in specimen QLT than in specimen QT. No austenite was found in all specimens Q, QL, QT and QLT. Specimen QLT showed purely ductile fracture mode at - 80 °C due to the refined effective grains. The greatly improved toughness is mainly attributed to the enhanced energy of crack propagation. The combination of refined microstructure, softened matrix and deformation of minor ‘soft’ IF during crack propagation led to the most superior toughness of specimen QLT among all specimens.
|
|
|
|
|
Cite this article: |
Fei Zhu,Feng Chai,Xiao-bing Luo, et al. Strengthening and toughening mechanism of a Cu-bearing highstrength low-alloy steel with refined tempered martensite/bainite (M/ B) matrix and minor inter-critical ferrite[J]. Journal of Iron and Steel Research International, 2021, 28(4): 464-478.
|
|
|
|
[1] |
Yu‑lu Li, Yue Zhao, Lin Shen, Hao Wu, He‑guo Zhu. Microstructure and mechanical properties of in situ (TiC + SiC)/FeCrCoNi high entropy alloy matrix composites[J]. JOURNAL OF IRON AND STEEL RESEARCH,INTERNATIONAL, 2021, 28(4): 496-504. |
[2] |
Hanqing Liu. Effects of metallic microstructures on fatigue fracture of Q345 steel[J]. JOURNAL OF IRON AND STEEL RESEARCH,INTERNATIONAL, 2020, 27(6): 702-709. |
[3] |
Hu Chen, Chi Zhang, Hao Chen, Zhi-gang Yang, Lei Chen. Understanding microstructure-evolution-dependent fracture behaviors in pearlitic steels[J]. JOURNAL OF IRON AND STEEL RESEARCH,INTERNATIONAL, 2020, 27(3): 334-341. |
[4] |
Xin-gang Liu, Can Wang, Qing-feng Deng, Bao-feng Guo. High-temperature fracture behavior of MnS inclusions based on GTN model[J]. JOURNAL OF IRON AND STEEL RESEARCH,INTERNATIONAL, 2019, 26(9): 941-952. |
[5] |
Xiao-wei Feng, Juan Xie, Wen-ying Xue, Yong-feng Shen, Hong-bo Wang, Zhen-yu Liu. Microstructure and nanoindentation hardness of shot-peened ultrafine-grained low-alloy steel[J]. JOURNAL OF IRON AND STEEL RESEARCH,INTERNATIONAL, 2019, 26(5): 472-482. |
[6] |
Wang-jun Peng, Guang-xin Wu, Yi Cheng, Jie-yu Zhang. Interface reaction of high-strength low-alloy steel with Al–43.4Zn–1.6Si (wt.%) metallic coating[J]. JOURNAL OF IRON AND STEEL RESEARCH,INTERNATIONAL, 2019, 26(12): 1304-1314. |
|
|
|
|