Grain size effect on shearing performance of copper foil: A polycrystal plasticity investigation

The existing experimental observations about the grain size effect on the shearing performance of copper foils lack material and mechanical interpretation. Hence, for the first time, the micro-blanking process of 100 mu m thick polycrystalline aggregates with different grain sizes and microstructures has been simulated based on the crystal plasticity framework. The obtained results visually displayed the different deformation modes of the coarse-and fine-grained materials. The grain refinement was found to be conducive for maintaining the regularity in the sheared edge. The orientation effect played an important role in the shearing process. Additionally, a correlation between the repeatability of the punching force and grain size was qualitatively developed, and the micro-hardness of the deformed material was calculated based on the flow stress and compared with the previous measurements. Further, the limitations of the presented simulation approach have been elaborated in detail, with multiple guidelines provided for modification. The findings reported in this paper contribute to an in-depth understanding of the cross-scaled shearing performance of the copper foil and the importance of the grain size effect.

Automated summary

For the first time, the micro-blanking process of polycrystalline aggregates with different grain sizes and microstructures was simulated based on the crystal plasticity framework. The results showed that grain refinement was beneficial for maintaining regularity in the sheared edge, and emphasized the importance of orientation effect. Additionally, a correlation between punching force repeatability and grain size was qualitatively established, and the micro-hardness of the deformed material was calculated. The limitations of the simulation approach were also discussed in detail, providing guidelines for future modifications.