Abstract
In this work we propose a new method to separate iron losses by removing low frequency tests and reducing the number of experiments. The article deals with methodologies that use numerical methods to find the mathematical model coefficients of magnetic loss separation in hysteresis loss (Wh), eddy current loss (Wed) and excess loss (Wex). Three methodologies are presented and depend on experimental tests such as (i) varying magnetic induction Bm and constant supply frequency (f) of 50 Hz, (ii) constant magnetic induction around 1 T and varying frequency. The first methodology is based on Newton’s method to solve the numerical system generated with experimental data from two laboratory experiments. These data were reported in past references. Another two methodologies are based on genetic algorithms (GA). One of them depends on experimental data from both experiments and the another depends on experimental data only from experiment (i). Results indicate that genetic algorithms method presents excellent solutions in comparison with other ones. The GA method with two tests allows a better representation of the experimental behavior of the sample with maximum errors varying from 1.10% to 0.20%. In GA method with one test, minimization varied from 6.924 × 10−05 to 3.186 × 10−05.
Highlights
Electrical machines have ferromagnetic material core whose magnetic behavior has been investigated extensively [1]-[17]
The hysteresis losses are obtained for different magnetic flux density levels at low frequency, called quasi-static tests, when the dynamic losses can be neglected
For the purpose of separating total magnetic loss (Wtotal) in: hysteresis loss (Wh), Eddy current loss (Wed) and excess loss (Wex), the three methodologies presented were applied to four cases
Summary
Electrical machines have ferromagnetic material core whose magnetic behavior has been investigated extensively [1]-[17]. Such studies model the magnetic behavior of the material, describe magnetic hysteresis phenomena and allow formulations for representing magnetic losses. The measured iron losses have shown that hysteresis and eddy current losses vary linearly with temperatures between 40 and 100 oC. The advantage of this model is its utility on the analysis of electromagnetic and thermal coupling for predicting iron loss and Brazilian Microwave and Optoelectronics Society-SBMO received 18 Jan 2021; for review 18 Jan 2021; accepted 3 May 2021
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