Analysis and characterization of dynamic recrystallization and grain structure evolution in friction stir welding of aluminum plates

The dynamic recrystallization (DRX) process and grain structure evolution during friction stir welding determine the final microstructure and performance of weld joints. In this study, Monte Carlo method is applied to develop a model for numerical simulation of dynamic recrystallization in friction stir welding of aluminum plates. An appropriate DRX nucleation model suitable for Monte Carlo simulation is selected, and the correlation of the Monte Carlo simulation step and the real time is calibrated. The transient evolution and the final distribution of grain structures in welds are predicted numerically. The calculated grain sizes in weld nugget zone are in good agreement with the experimentally measured ones. The dynamic recrystallization mechanism during friction stir welding of 1060 aluminum plate is analyzed by combining the finite element simulation and Monte Carlo simulation results with the characterization results of electron backscatter diffraction. It is found that along the material flowing path during friction stir welding, the main DRX mechanisms are different at leading, retreating and trailing sides around the tool, and the tool rotation speed (associated with the heat input level) determines which type of DRX is easier to occur at different positions along material flowing path. (C) 2021 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Automated summary

In this study, a model for numerical simulation of dynamic recrystallization in friction stir welding of aluminum plates was developed using the Monte Carlo method. The predicted evolution of grain structures in the welds showed good agreement with experimentally measured values. The analysis revealed different DRX mechanisms along the material flowing path during friction stir welding, with the tool rotation speed determining the type of DRX that occurs at different positions.