Core-Loss Prediction for Non-Oriented Electrical Steels Based on the Steinmetz Equation Using Fixed Coefficients With a Wide Frequency Range of Validity

被引:27
|
作者
Novak, Gasper [1 ]
Kokosar, Janko [1 ]
Nagode, Ales [2 ]
Petrovic, Darja Steiner [3 ]
机构
[1] RCJ, Doo, Dept Dev Steels & Technol, Jesenice 4270, Slovenia
[2] Univ Ljubljana, Fac Nat Sci & Engn, Ljubljana 1000, Slovenia
[3] Inst Met & Technol, Dept Metall Mat & Technol, Ljubljana 1000, Slovenia
来源
IEEE TRANSACTIONS ON MAGNETICS | 2015年 / 51卷 / 04期
关键词
Core loss; electrical steel; fixed coefficient; frequency; Steinmetz equation; IRON LOSS CALCULATION; HYSTERESIS LOSS; POWER LOSSES; LOSS MODELS; MACHINES; ANISOTROPY; SHEETS; FLUX; LAW;
D O I
10.1109/TMAG.2014.2354317
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
An accurate prediction of the core losses is crucial for the optimal design and selection of the electrical steels used in electrical devices. The measured specific core losses are divided into three main parts, i.e., the eddy-current loss, the hysteresis loss, and the excess loss. In this paper, a simplified, predictive model for the core loss in a non-oriented electrical steel using fixed coefficients is proposed. The coefficients for a wide frequency spectrum up to 10 000 Hz of validity for the prediction of the eddy current, the hysteresis, and the excess components were calculated with respect to a sinusoidal voltage using the modified Steinmetz equation and a polynomial regression analysis.
引用
收藏
页数:7
相关论文
共 9 条
  • [1] Effects of Sn Addition on Core Loss and Texture of Non-Oriented Electrical Steels
    DONG Hao1
    2.Functional Materials Branch
    3.School of Material and Metallurgy
    JournalofIronandSteelResearch(International), 2009, 16 (06) : 86 - 89
  • [2] Effects of Sn Addition on Core Loss and Texture of Non-Oriented Electrical Steels
    Dong Hao
    Zhao Yu
    Yu Xiao-jun
    Lian Fa-zeng
    JOURNAL OF IRON AND STEEL RESEARCH INTERNATIONAL, 2009, 16 (06) : 86 - 89
  • [3] Effects of Sn addition on core loss and texture of non-oriented electrical steels
    Hao Dong
    Yu Zhao
    Xiao-jun Yu
    Fa-zeng Lian
    Journal of Iron and Steel Research International, 2009, 16 : 86 - 89
  • [4] Effect of Material Properties on Core Loss in Switched Reluctance Motor using Non-Oriented Electrical Steels
    Kartigeyan, J.
    Ramaswamy, M.
    JOURNAL OF MAGNETICS, 2017, 22 (01) : 93 - 99
  • [5] Improved Model Based on the Modified Steinmetz Equation for Predicting the Magnetic Losses in Non-Oriented Electrical Steels That is Valid for Elevated Temperatures and Frequencies
    Novak, G.
    Kokosar, J.
    Bricelj, M.
    Bizjak, M.
    Petrovic, D. Steiner
    Nagode, A.
    IEEE TRANSACTIONS ON MAGNETICS, 2017, 53 (10)
  • [6] Effect of non-metallic precipitates and grain size on core loss of non-oriented electrical silicon steels
    Wang, Jiayi
    Ren, Qiang
    Luo, Yan
    Zhang, Lifeng
    JOURNAL OF MAGNETISM AND MAGNETIC MATERIALS, 2018, 451 : 454 - 462
  • [7] Use of quasi-static loops of magnetic hysteresis in loss prediction in non-oriented electrical steels
    Szczyglowski, Jan
    PHYSICA B-CONDENSED MATTER, 2020, 580 (580)
  • [8] Correlation between Cutting Clearance, Deformation Texture, and Magnetic Loss Prediction in Non-Oriented Electrical Steels
    Fuzer, Jan
    Dobak, Samuel
    Petryshynets, Ivan
    Kollar, Peter
    Kovac, Frantisek
    Slota, Jan
    MATERIALS, 2021, 14 (22)
  • [9] Machine Learning to Predict the Effect of Stress on Iron Loss and Its Frequency Dependence in Non-Oriented Electrical Steels
    Hayakawa, Kyohei
    Matsui, Isao
    Sekine, Yuichi
    Maeguchi, Takaharu
    MATERIALS TRANSACTIONS, 2024, 65 (08) : 977 - 986
1