Modelling of austenite decomposition transformation of heat affected zone in API-X65 and X70 pipeline steels
Subject Areas : journal of New Materials
1 - Islamic Azad University, Saveh Branch
Keywords: microalloyed steel, heat affected zone, Austenite, dilatometry,
Abstract :
In this study, the simulation of the heat affected zone of welding was carried out based on the practical conditions of four-wire submerged arc welding in two X65 and X70 microalloy steel. Initially, thermal cycles of the heat affected zone were analyzed. By applying heating and cooling thermal cycles to peak temperatures of 950, 1150 and 1350 °C, in a dilatometric device, transformation behavior and microscopic structure were studied. With increasing peak temperature in transformation, despite the constant cooling rate (23 ° C / s) in the range of 800 to 500 ° C, the start and end temperatures of transformation are delayed and shear structures replace polygonal structures. The reasons are the coarsening of austenite grains, the dissolution of niobium carbide precipitates and the solute-drag effect of solved niobium in austenite.The size of the shear packs and the size of the austenite grains are also noticeably larger. By analyzing the dilatometry results, continuous cooling diagram and the kinetics of decomposition of austenite were investigated. Austenite decomposition modeling was performed using the JMAK classic equation. It was found that the parameter n has a small dependence on temperature; while the parameter k is strongly dependent to temperature, phase fraction transformed and austenite grain size. The results of modeling of phase transformations using the JMAK equation were in good agreement with the dilatometric results.
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