The magnetic properties of commercial dual-phase (DP) steels (DP600, DP800 and DP1000 grades) were evaluated using initial permeability, incremental permeability and coercivity and correlated with the key microstructural differences between the grades. The ferrite grain sizes and ferrite fractions have been compared with the magnetic parameters obtained from minor and major magnetisation loops within each DP grade. It has been revealed that the incremental permeability increases with the applied magnetic field amplitude to reach a peak and then drops at a higher magnetic field, with the values being different for the three DP grades at a lower field and converging to a similar permeability value at the high field. The effects of ferrite grain size and phase fraction on the incremental permeability are considered, and it has been shown that the influence of ferrite grain boundaries on magnetic permeability is more dominant than the effect of ferrite fraction in commercial DP steel samples. An analysis of the correlation between coercivity and initial permeability with tensile strength shows that the initial permeability provides a slightly better prediction of strength for the steels examined, which is believed to be due to the fact that a combination of reversible and irreversible domain components affect the coercivity value, while the initial permeability is predominantly affected by reversible domain movements. Based on the trend between incremental permeability and applied magnetic field and the commercial EM sensor (EMspec) operating parameters, the effect of lift-off and hence magnetic field strength on the sensitivity to DP steel properties can be assessed.
A set of IF steel specimens, at different states of recrystallisation (commercially cold rolled and annealed to give partially recrystallised and fully recrystallised microstructures) and accordingly different texture components have been used to investigate the measurement and prediction of magnetic anisotropy. A finite element microstructure model that considers crystallographic texture has been used for the prediction of magnetic anisotropy to compare to the measured values, with comparable anisotropy being observed. The results show that the proposed deployable non-destructive approach (U-shaped electromagnetic sensor that can be placed onto a sheet sample) is promising for the quick evaluation of the magnetic anisotropy in IF steels.
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