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Aging kinetics and mechanical properties of copper-bearing low-carbon HSLA-100 microalloyed steel
The precipitation kinetics of HSLA-100 steel and the correlation between tensile and impact properties were studied. According to the modified Johnson—Mehl—Avrami—Kolmogorov (JMAK) analysis and based on the analysis of the time corresponding to the transformed fraction of 0.5 (t0.5), the activation energy for the precipitation of copper during aging of martensite was determined as ˜111 and 105 kJ/mol, respectively. These values are much smaller than the activation energy for the diffusion of Cu in α-iron, which was related to the effect of high dislocation density of the quenched martensitic microstructure on the aging process. These results were verified based on the diffusional calculations. Based on the analysis of mechanical behavior, no reasonable correlation was found between strength of the material and the impact energy. However, the impact energy was found to be proportional to the UTS-YS, where the latter is an indicator of the work-hardening capability of the material. This revealed that the work-hardening capacity of the material is a much more important factor for determining the impact toughness compared to its strength.
Aging kinetics and mechanical properties of copper-bearing low-carbon HSLA-100 microalloyed steel
The precipitation kinetics of HSLA-100 steel and the correlation between tensile and impact properties were studied. According to the modified Johnson—Mehl—Avrami—Kolmogorov (JMAK) analysis and based on the analysis of the time corresponding to the transformed fraction of 0.5 (t0.5), the activation energy for the precipitation of copper during aging of martensite was determined as ˜111 and 105 kJ/mol, respectively. These values are much smaller than the activation energy for the diffusion of Cu in α-iron, which was related to the effect of high dislocation density of the quenched martensitic microstructure on the aging process. These results were verified based on the diffusional calculations. Based on the analysis of mechanical behavior, no reasonable correlation was found between strength of the material and the impact energy. However, the impact energy was found to be proportional to the UTS-YS, where the latter is an indicator of the work-hardening capability of the material. This revealed that the work-hardening capacity of the material is a much more important factor for determining the impact toughness compared to its strength.
Aging kinetics and mechanical properties of copper-bearing low-carbon HSLA-100 microalloyed steel
Archiv.Civ.Mech.Eng
Sohrabi, M. J. (Autor:in) / Mirzadeh, H. (Autor:in) / Mehranpour, M. S. (Autor:in) / Heydarinia, A. (Autor:in) / Razi, R. (Autor:in)
Archives of Civil and Mechanical Engineering ; 19 ; 1409-1418
01.12.2019
10 pages
Aufsatz (Zeitschrift)
Elektronische Ressource
Englisch
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