Quantification of magnetic flux density in non-oriented electrical steel sheets by analysis of texture components

In order to quantify the impact of crystallographic texture on the variation of magnetic flux density B(α) in non-oriented electrical steel, two sheet samples with identical chemical composition were produced in a way to achieve different textures. A correlation between the values of B(α  ) and an anisotropy parameter A(h→) obtained from the sheet textures was established. In turn, this correlation was used to compute in-plane variations of B(α) for various single crystal orientations as well as various characteristic polycrystal texture components.Since non-oriented electrical steel is mainly used in applications with changing directions of magnetization the planar magnetic flux density B¯, which averages the in-plane variation of B(α  ), is an important measure of the overall magnetizing ability. A high planar magnetic flux density B¯ is achieved by increasing texture components with their {0 0 1} poles close to the sheet normal direction, perpendicular to the sheet plane, while suppressing texture components whose {0 0 1} poles deviate from the normal direction by more than 30°.

► Impact of texture on magnetic properties was studied in electrical steel sheets.
► Magnetic flux density B(α  ) was quantified by anisotropy parameter A(h→)).
► An empirical relationship between B(α  ) and A(h→) was established.
► In-plane variations of B(α) for various polycrystal texture components were computed.
► High planar magnetic flux density is achieved by increasing {0 0 1}‖ND components.