Grain Size Influence on the Magnetic Property Deterioration of Blanked Non-Oriented Electrical Steels

Non-oriented electrical steel sheets are applied as a core material in rotors and stators of electric machines in order to guide and magnify their magnetic flux density. Their contouring is often realized in a blanking process step, which results in plastic deformation of the cut edges and thus deteriorates the magnetic properties of the base material. This work evaluates the influence of the material's grain size on its iron losses after the blanking process. Samples for the single sheet test were blanked at different cutting clearances (15 mu m-70 mu m) from sheets with identical chemical composition (3.2 wt.% Si) but varying average grain size (28 mu m-210 mu m) and thickness (0.25 mm and 0.5 mm). Additionally, in situ measurements of blanking force and punch travel were carried out. Results show that blanking-related iron losses either increase for 0.25 mm thick sheets or decrease for 0.5 mm thick sheets with increasing grain size. Although this is partly in contradiction to previous research, it can be explained by the interplay of dislocation annihilation and transgranular fracturing. The paper thus contributes to a deeper understanding of the blanking process of coarse-grained, thin electrical steel sheets.

Automated summary

This study evaluates the impact of grain size on iron losses in non-oriented electrical steel sheets after the blanking process. The results show that increasing grain size leads to increased iron losses in 0.25 mm thick sheets, while iron losses decrease in 0.5 mm thick sheets, contrary to previous research. This can be explained by the interplay of dislocation annihilation and transgranular fracturing.