Improving Global Ferromagnetic Characteristics of Laminations by Heterogeneous Deformation

During electrical machine manufacturing, the process may induce plastic mechanical strains, especially in the magnetic core. However, magnetic properties are highly sensitive to the material mechanical state. Thus, the performances of electrical machines, which also rely on the magnetic material properties, are often deteriorated. This article proposes an approach to reduce the impact of the forming process on the magnetic core performances by creating high localized heterogeneous deformations instead of having a low homogeneous deformation distributed on the whole structure. A NO (non-oriented) FeSi (1.3%) electrical steel (M330-35A) is characterized after uniaxial tensile test. Samples are deformed either in heterogeneous or in homogeneous ways while keeping the same global deformation. Experimental measurements show that, for the same displacement value, the heterogeneous configuration, with localized strain, deteriorates less the global magnetic properties than the homogeneous configuration. These results are supported by a magneto-mechanical modeling approach that predicts accurately the physical behavior of the test samples.

Automated summary

In the process of electrical machine manufacturing, the forming process may impact the magnetic core performance. The article suggests reducing this impact by creating high localized heterogeneous deformations rather than low homogeneous deformation. Experimental measurements demonstrate that localized strain in a heterogeneous configuration has a smaller impact on global magnetic properties compared to a homogeneous configuration.