The dependences of the power loss per cycle on frequency f and amplitude flux density Bm have been investigated for the three main original magnetic states in five sorts of Fe-based nanocrystalline soft magnetic alloys in the ranges of 10 Hz≤f≤1000 Hz and 0.4 T≤ Bm ≤1.0 T. The total loss P is decomposed into the sum of the hysteresis loss Physt, the classical eddy current loss Pei and the excess loss Pexc.Physt has been found to be proportional to Bm2 and f. The behavior of Pexc/f vs f being equivalent to p/f vs f clearly exhibits nonlinearity in the range not more than about 120 Hz, whereas the behavior of P/f vs f roughly shows linearity in the range far above 100 Hz and not more than 1000 Hz. In the range up to 1000 Hz, Physt is dominant in the original high permeability state and the state of low residual flux density, whereas Pexc in the state of high residual flux density is dominant in the wider range above about 100 Hz. The framework of the statistical theory of power loss has been used for representing the behavior of Pexc/f vs f. It has been found that the number n of the simultaneously active "Magnetic Objects" linearly varies as n = no +Hexc/HO as a function of the dynamic field Hexc in the range below about 120 Hz, whereas n approximately follows a law of the form n = no + (Hexc/Ho)m with 1 < m < 2 in the range far above 100 Hz and not more than 1000 Hz. The values of the field Ho in principle related to the microstructure and the domain structure have been calculated for the three states.
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机译:平成28年度论文赏受赏轮文:Effect of Si/Fe Composition, Substrate Temperature, and Substrate Orientation on the Structure and Magnetic Properties of Fe-Si Alloy Film