Microstructural development and mechanical properties during hot rolling and annealing of an automotive steel combining TRIP/TWIP effects
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This research was carried out in order to study the variations of microstructure and mechanical properties of 9 wt%25 Mn steel, which was produced by ingot casting, hot rolling and intercritical annealing (IA). Thermodynamic simulation of the corresponding phase diagram for the experimental composition allowed to select a suitable intercritical annealing temperature of 680 °C. After this step, we found a microstructure composed by lamellar ferrite within an austenite matrix. Austenite content was 47%25 for the hot rolled sample, while it was 36%25 and 52%25 for two and 6 h of intercritical annealing, respectively. Unfortunately, austenite phase started to coarsen at 6 h and ferrite lamellas were also fragmented, causing an important hardness and elongation reduction. Mechanical properties were measured comparing hot rolling samples vs. annealed samples at 680 °C for 2 h. We found that an excellent combination of UTS (ultimate tensile strength)of 1200 MPa, an elongation of almost 60%25 and an impact energy of 55 J could be obtained after IA for 2 h. These results, with the exception of UTS, significantly exceeded the values displayed by hot rolling condition and were associated with the stability of austenite which increased during annealing. Finally, we demonstrated that only TRIP (transformation induced plasticity)effect was present in the hot rolled sample during tension testing, in contrast with the annealed sample in which austenite content only diminished 12%25, which indicates that TWIP (twinning induced plasticity)effect was also effective. © 2019 Elsevier B.V.
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Mechanical properties; Metals and alloys; Microstructure; Scanning electron microscopy Annealing; Austenite; Ferrite; Hot rolling; Manganese steel; Mechanical properties; Microstructure; Plasticity; Plasticity testing; Scanning electron microscopy; Tensile strength; Tensile testing; Transformation Induced Plasticity steel; Intercritical annealing temperatures; Metals and alloys; Microstructural development; Microstructure and mechanical properties; Thermodynamic simulations; Transformation induced plasticity; Twinning-induced plasticities; Ultimate tensile strength; Steel research
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