Evolution of microstructure and precipitation state during thermomechanical processing of a X80 microalloyed steel

► Industrial hot rolling simulation of high-strength X80 low-carbon microalloyed steel. ► Austenite hardening role on microstructure and precipitation during and after rolling. ► Finer and more equiaxed ferrite grains after cooling from severely deformed austenite. ► More acicular ferrite and higher...

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Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2011-05, Vol.528 (13), p.4761-4773
Main Authors: Gomez, Manuel, Valles, Pilar, Medina, Sebastián F.
Format: Article
Language:English
Subjects:
Acicular ferrite
Applied sciences
Cross-disciplinary physics: materials science
rheology
Elasticity. Plasticity
Exact sciences and technology
Heat treatment
Materials science
Mechanical properties and methods of testing. Rheology. Fracture mechanics. Tribology
Metals. Metallurgy
Microalloyed steel
Other heat and thermomechanical treatments
Physics
Pipeline
Precipitation
Production techniques
Thermomechanical processing
Thermomechanical treatment
Transmission electron microscopy
Treatment of materials and its effects on microstructure and properties
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Summary:► Industrial hot rolling simulation of high-strength X80 low-carbon microalloyed steel. ► Austenite hardening role on microstructure and precipitation during and after rolling. ► Finer and more equiaxed ferrite grains after cooling from severely deformed austenite. ► More acicular ferrite and higher strength if last finishing passes are less intense. ► Cuboidal TiNbCN particles exist from reheating and finer NbMoCN appears near 1000 °C. A series of anisothermal hot torsion tests were carried out to simulate hot rolling on a high-strength low-carbon CMnNbMoTi microalloyed steel corresponding to an industrial X80 grade for pipeline construction. Mean Flow Stress was graphically represented against the inverse of temperature to characterize the evolution of austenite microstructure during rolling, which was also studied by optical microscopy and SEM on samples quenched from several temperatures. On the other hand, particles precipitated at different temperatures during rolling were analyzed by means of TEM using the carbon extraction replica technique and their size distribution and mean size were determined, as well as their morphology, nature and chemical composition. The effect of rolling temperature and austenite strengthening obtained at the end of thermomechanical processing on final microstructure and precipitation state was studied. Austenite strengthening was characterized by means of the parameter known as accumulated stress (Δ σ). It was found that ferrite grains are finer and more equiaxed when the austenite is more severely deformed during finishing (higher values of Δ σ) but lower values of Δ σ generate a higher density of acicular structures after cooling, which should improve the balance of mechanical properties. The increase in strength associated to acicular ferrite compared to polygonal ferrite is revealed by the higher values of Vickers microhardness measured on samples corresponding to low Δ σ. On the other hand, (Ti, Nb)-rich carbonitrides can be found from reheating and their size keeps a constant value near 20–30 nm during thermomechanical processing. A second population of much finer (Nb, Mo)-rich carbonitrides whose size is close to 5 nm forms from lower temperatures, near 1000 °C. The accomplishment of two different levels of Δ σ at the end of hot rolling schedule does not seem to introduce major differences in precipitation state before final cooling.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2011.02.087