The Effects of Sheet Thickness and Excitation Frequency on Hysteresis Loops of Non-Oriented Electrical Steel

Chwastek, Krzysztof

doi:10.3390/s22207873

Cited by 4 publications

(13 citation statements)

References 67 publications

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“…The present paper is a follow up of previous research devoted to modeling hysteresis curves under an increased excitation frequency [1]. The aim of the paper is to demonstrate the usefulness of a viscous-type equation, considered previously by Zirka et al [2], as a means to describe the so-called excess field component.…”

Section: Introductionmentioning

confidence: 71%

“…The issue of loss separation in soft magnetic materials may be tackled from different perspectives, and a recent review on the subject can be found in [1]. Here, we follow the so-called two-term separation scheme, in which field strength at an increased excitation frequency is computed from…”

Section: The Viscous-type Equationmentioning

confidence: 99%

“…in which H stat (B) corresponds to the material response under slow driving (quasi-static excitation); the exponent 1/ν is fractional, and it accounts for viscous effects mostly due to eddy currents in different time and spatial scales in the conductive material, whereas r(B) = K 1 − (B/J sat ) 2 , where J sat is the saturation polarization and the proportionality coefficient K is found to vary both on induction and its rate, K = K(B, dB/dt) [1].…”

Section: The Viscous-type Equationmentioning

confidence: 99%

“…As indicated in the previous study [1], the starting point for the analysis is the dependence of coercive field strength vs. frequency. Figure 4 depicts the experimental dependence H c = H c ( f ) for the examined Metglas core.…”

Section: The Viscous-type Equationmentioning

confidence: 99%

“…As indicated in the previous study [1], the starting point for the analysis is the dependence of coercive field strength vs. frequency. Figure 4 The dependencies H c = H c ( f ) were fitted to a relationship, power law + free term, and thus H c = H c0 + c f 1/ν .…”

Section: The Viscous-type Equationmentioning

confidence: 99%

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Modeling Dynamic Hysteresis Curves in Amorphous Magnetic Ribbons

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A description of magnetic hysteresis is important for the prediction of losses in soft magnetic materials. In this paper, a viscosity-type equation is used to describe dynamic hysteresis loops in an amorphous ring core for symmetric excitation, as prescribed by international standards. The value of the exponent appearing in the viscosity-based equation can be assumed to be constant if the maximum induction is away from the saturation value. The viscosity-type equation is used to describe the shape variation of magnetization curves due to eddy currents in different time and space scales. Modeling is carried out for various excitation frequencies and induction amplitudes. The discrepancies between the experimental and modeled curves (and also losses) are acceptable in the wide range of the frequency and maximum induction. The paper indicates that the viscosity-type effects, mostly due to eddy currents generated in the conductive material, play an important role in energy dissipation at increased excitation frequencies. The modeling results might be interesting to the designers of magnetic circuits.

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Section: Introductionmentioning

confidence: 71%

Section: The Viscous-type Equationmentioning

confidence: 99%

Section: The Viscous-type Equationmentioning

confidence: 99%

Section: The Viscous-type Equationmentioning

confidence: 99%

Section: The Viscous-type Equationmentioning

confidence: 99%

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Modeling Dynamic Hysteresis Curves in Amorphous Magnetic Ribbons

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The Effective Field in the T(x) Hysteresis Model

et al. 2023

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Hysteresis loops constitute the source of important information for the designers of magnetic circuits in power transformers. The paper focused on the possibility to interpret the phenomenological T(x) model in terms of effective field vs. magnetization dependence. The interdependence of anhysteretic curve and hysteresis loops was emphasized. The concept of the anhysteretic plane introduced at the end of the last century by Sablik and Langman was subject to a tangible interpretation within the hyperbolic model framework. A novel geometric interpretation of the “effective field” related to the concept of affine transformation was introduced. It was shown in the paper that minor hysteresis loops of grain-oriented electrical steel may be described with the proposed formalism.

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A Methodology for Calculating the R-L Parameters of a Nonlinear Hysteretic Inductor Model in the Time Domain

et al. 2023

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The aim of this paper is to present a methodology for the calculation of the R-L parameters of a model of a nonlinear hysteretic inductor. The methodology is based on the analysis of the instantaneous magnetising power calculated from the hysteresis loop of the inductor and is completely developed in the time domain. The instantaneous magnetising power is firstly separated into the oscillatory and absorbed components. Thereafter, the parameter R is calculated using the absorbed component and the parameter L using the oscillatory component. The methodology is validated through the comparison of the results for parameters R and L obtained with the proposed method and the existing method based on the Poynting theorem. The validation is demonstrated on the specific simulated cases with idealised parameters of a nonlinear circuit. Additionally, the paper presents results for the parameters R and L calculated from the hysteresis loops measured at frequencies from 1 to 300 Hz. Furthermore, the fitting functions representing the variation of these parameters with the rate of change of magnetic flux density, and the corresponding results, are presented in the paper. A discussion of all the results presented and applicability of the methodology proposed, as well as the concluding remarks, are given thereafter.

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The Effects of Sheet Thickness and Excitation Frequency on Hysteresis Loops of Non-Oriented Electrical Steel

Cited by 4 publications

References 67 publications

Modeling Dynamic Hysteresis Curves in Amorphous Magnetic Ribbons

Modeling Dynamic Hysteresis Curves in Amorphous Magnetic Ribbons

The Effective Field in the T(x) Hysteresis Model

A Methodology for Calculating the R-L Parameters of a Nonlinear Hysteretic Inductor Model in the Time Domain

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