This paper discusses the anomalous loss behavior in two electrical steels types. Starting from a non oriented electrical steel coil, three groups of samples with different grain sizes were produced. Grain oriented steel samples were produced from a commercially available material. The experimental procedure was performed by means of magnetic properties measurements using an Epstein frame. A procedure to draw the hysteresis curve of the anomalous loss is proposed. The results reported that anomalous loss has a different behavior when the two electrical steel types are compared. In non oriented steels anomalous loss is concentrated at the low induction region. In grain oriented steels, a remarkable participation of high induction region is ob...
For loss prediction of a transformer it is required to model the loss of its core, constructed out o...
The paper focuses on modeling the rate dependence of hysteresis loops in conductive magnetic materia...
Manufacturing the magnetic cores in electrical machines impacts the magnetic performance of the elec...
This paper discusses the anomalous loss behavior in two electrical steels types. Starting from a non...
The aim of this work was to investigate the influence of microstructural features on the soft magnet...
Two alloys of nonoriented electrical steel, with 2.45 and 3.3 %Si, respectively, had their magnetic ...
The interpretation of the effect of plastic deformation on the calculated excess loss component (ano...
This paper is intended to stimulate discussion of some effects of not properly accounting for materi...
Loss separation experiments on non-oriented and grain-oriented 3.2 wt.% SiFe electrical steels have ...
An experimental method to characterize the magnetic properties of Grain Oriented Electrical Steel in...
Assuming that different energy dissipation mechanisms are at work along hysteresis, a hysteresis los...
In real electromagnetic devices the non-oriented electrical steel is often subjected to various mech...
Power transformer design requires to model the loss and hysteresis behavior of the laminated steel c...
Abstract. The efficiency of electrical machines depends among other things on the specific total los...
For loss prediction of a transformer it is required to model the loss of its core, constructed out o...
The paper focuses on modeling the rate dependence of hysteresis loops in conductive magnetic materia...
Manufacturing the magnetic cores in electrical machines impacts the magnetic performance of the elec...
This paper discusses the anomalous loss behavior in two electrical steels types. Starting from a non...
The aim of this work was to investigate the influence of microstructural features on the soft magnet...
Two alloys of nonoriented electrical steel, with 2.45 and 3.3 %Si, respectively, had their magnetic ...
The interpretation of the effect of plastic deformation on the calculated excess loss component (ano...
This paper is intended to stimulate discussion of some effects of not properly accounting for materi...
Loss separation experiments on non-oriented and grain-oriented 3.2 wt.% SiFe electrical steels have ...
An experimental method to characterize the magnetic properties of Grain Oriented Electrical Steel in...
Assuming that different energy dissipation mechanisms are at work along hysteresis, a hysteresis los...
In real electromagnetic devices the non-oriented electrical steel is often subjected to various mech...
Power transformer design requires to model the loss and hysteresis behavior of the laminated steel c...
Abstract. The efficiency of electrical machines depends among other things on the specific total los...
For loss prediction of a transformer it is required to model the loss of its core, constructed out o...
The paper focuses on modeling the rate dependence of hysteresis loops in conductive magnetic materia...
Manufacturing the magnetic cores in electrical machines impacts the magnetic performance of the elec...