Effect of Bainite to Ferrite Yield Strength Ratio on the Deformability of Mesostructures for Ferrite/Bainite Dual-Phase Steels

• Published in: Materials Vol. 14; no. 18; p. 5352
• Main Authors: Qiao, Gui-Ying, Zhao, Zhong-Tao, Shi, Xian-Bo, Shan, Yi-Yin, Gu, Yu, Xiao, Fu-Ren
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 16.09.2021; MDPI
• Subjects: Bainite; Compatibility; Cooling; deformability; Deformation; deformation compatibility; Deformation effects; Dual phase steels; Elongation; F/B dual-phase steel; Formability; High strength low alloy steels; Mechanical properties; Morphology; simulation; Steel; Strain concentration; Strain hardening; Strain localization; strength difference in bainite to ferrite; Stress concentration; Structural steels; Tensile properties; Tensile strength; Yield strength; Yield stress
• ISSN: 1996-1944; 1996-1944
• DOI: 10.3390/ma14185352

The strength and plasticity balance of F/B dual-phase X80 pipeline steels strongly depends on deformation compatibility between the soft phase of ferrite and the hard phase of bainite; thus, the tensile strength of ferrite and bainite, as non-negligible factors affecting the deformation compatibility, should be considered first. In this purely theoretical paper, an abstract representative volume elements (RVE) model was developed, based on the mesostructure of an F/B dual-phase X80 pipeline steel. The effect of the yield strength difference between bainite and ferrite on tensile properties and the strain hardening behaviors of the mesostructure was studied. The results show that deformation first occurs in ferrite, and strain and stress localize in ferrite prior to bainite. In the modified Crussard-Jaoul (C-J) analysis, as the yield strength ratio of bainite to ferrite (σy,B/σy,F) increases, the transition strain associated with the deformation transformation from ferrite soft phase deformation to uniform deformation of ferrite and bainite increases. Meanwhile, as the uncoordinated deformation of ferrite and bainite is enhanced, the strain localization factor (SLF) increases, especially the local strain concentration. Consequently, the yield, tensile strength, and yield ratio (yield strength/tensile strength) increase with the increase in σy,B/σy,F. Inversely, the strain hardening exponent and uniform elongation decrease.