Temperature and Frequency Dependence of Magnetic Losses in Fe-Co

We investigate the temperature dependence of the energy loss W(f) of 0.10 and 0.20 mm thick Fe-Co-V sheets (Vacoflux (R) and Vacodur (R)) in the range-50(degrees)C <= T <= 155(degrees)C. The measurements, performed from DC to f = 5 kHz on ring samples and Epstein strips, show that W(f) passes through a minimum value around room temperature at all tested polarization values (1.0 <= J(p) <= 1.9 T). The largest effect occurs under quasi-static regime and declines with frequency, depending on the sheet thickness and the ensuing role of the dynamic loss. The somewhat abnormal increase of the quasi-static loss W-hyst with temperature, which contrasts with a concurrent decrease of the magneto crystalline anisotropy constant, is interpreted in terms of temperature-dependent internal stresses and their change with T. The stresses are assumed to derive from the different thermal expansion coefficients of the ordered and disordered structural phases, a conclusion made plausible by the highly magnetostrictive properties of the material, dwelling in a low anisotropy environment. The AC properties are treated by adapting the loss decomposition to the inception and development of a non-uniform induction profile across the sheet thickness (skin effect) at high frequencies. The classical loss component is calculated via the numerical solution of the Maxwell's diffusion equation, where the magnetic constitutive equation of the material is identified with the normal magnetization curve. It turns out that the so-found W-class(f) and the resulting excess loss W-exc(f) are moderately dependent on temperature and W(f) eventually tends towards a slow monotonical decrease with Tat the highest frequencies.

Automated summary

This study investigates the temperature dependence of energy loss in Fe-Co-V sheets. Results show that energy loss reaches a minimum value at room temperature and is most significant under quasi-static conditions. The changes in internal stress due to temperature are identified as the main factor affecting energy loss. At high frequencies, the skin effect leads to non-uniform induction and impacts AC properties.