Abstract
We investigate in theory and experiment the frequency dependence of magnetic losses in Grain-Oriented 0.29 mm thick high-permeability steel sheets up to 10 kHz. Such an unusually broad frequency range, while responding to increasing trends towards high-frequency regimes in applications, is conducive to a complex evolution of the magnetization process, as imposed by increasing frequencies to a non-linear high-permeability saturable material. We show that the concept of loss decomposition, supported by observations of the domain wall dynamics through Kerr experiments, is effective in the assessment of the broadband frequency dependence of the energy loss. By calculating, in particular, the instantaneous and time averaged macroscopic induction profiles across the sheet thickness through the Maxwell’s diffusion equation, the classical loss component Wclass, versus frequency f and peak polarization Jp, is obtained. A simplified theoretical approach is pursued in this case by identifying the normal magnetization curve with the magnetic constitutive equation of the material. While the hysteresis loss Whyst is shown to invariably increase with frequency, the excess loss Wexc, the quantity directly associated with the eddy currents circulating around the moving domain walls, tends to vanish upon increasing both frequency and induction values. The Kerr experiments actually show that, while the oscillating 180° domain walls can adjust to the depth of the induction profile by bowing at low Jp values, the magnetization reversal at high inductions and high frequencies occurs by inward motion of symmetric fronts originating at the sheet surface, according to a classical framework.
Highlights
Recent trends in electrical energy generation and transmission are guided by the growing role of heterogeneous and distributed renewable sources
The loss properties have been assessed in the framework of the loss separation concept, generalized to cover the skin effect phenomena in the high-frequency region. We aim in this way at retrieving physical information on the broadband magnetization process in materials nowadays exposed to widening applicative areas, while overcoming the limitations of the empiricalphenomenological approaches proposed in the available literature
Looking for a manageable numerical treatment, the actual hysteretic magnetic constitutive equation is identified with the normal magnetization curve, which is inserted in the Maxwell’s diffusion equation
Summary
Recent trends in electrical energy generation and transmission are guided by the growing role of heterogeneous and distributed renewable sources. Scitation.org/journal/adv constitutive law derived from a dynamic hysteresis model.10–12 It is a complex approach, where one applies the statistics of the moving domain walls (dw) at the scale of the single finite element, which is small compared to the sheet thickness. It was suggested that, where high peak polarization values are involved in GO Fe-Si (near-rectangular loop), a step-like (saturating) magnetic constitutive law coupled to the Maxwell’s diffusion equation, to be solved numerically or analytically, applies at all frequencies. The calculation is performed by means of a simple numerical model, lumping in the normal magnetization curve the constitutive equation of the material This permits us to separately determine the frequency dependent hysteresis Whyst(f ) and excess Wexc(f ) loss components and their evolution under increasing skin effect.
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