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Possible Future Trends and Research Challenges related to 1 & 2 D Magnetic Properties of Soft Magnetic Materials

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Wybrane pełne teksty z tego czasopisma
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Warianty tytułu
PL
Trendy i wyzwania w badaniu jedno i dwuosiowych parametrów materiałów magnetycznie miękkich
Języki publikacji
EN
Abstrakty
EN
One and two dimensional magnetisation studies of bulk soft magnetic materials have been researched and characterised over the past 100 years. Initially, focus was on dc rotational hysteresis and this has evolved to studies of losses permeability, and magnetostriction, mainly of electrical steels, under controlled complex magnetisation of the type known to locally occur in rotating machine and transformer cores. This paper briefly summarises present knowledge and then some new and unsolved problems of interest or potential industrial importance are reviewed.
PL
Jedno- i dwuosiowe problem magnesowania materiałów magnetycznych miękkich były badane od niemal stu lat. Początkowo koncentrowano się na rotacyjnej histerezie dc i stąd określano takie parametry jak przenikalność, straty czy magnetostrykcję przy magnesowaniu rotacyjnym. Artykuł prezentuje obecny stan wiedzy oraz prognozuje przyszłe kierunki badań w tej dziedzinie.
Rocznik
Strony
11--16
Opis fizyczny
Bibliogr. 37 poz., rys., tab., wykr.
Twórcy
autor
  • Wolfson Centre for Magnetics, School of Engineering, Cardiff University, The Parade, Cardiff, Wales, Mosesaj@cf.ac.uk
Bibliografia
  • [1] Sievert J. Keynote address at 1 & 2 DM Conference, Oita, Japan, November 2010
  • [2] Gans R, et al., On rotational hysteresis, Arch Electrotech, 3 (1915), 139-150
  • [3] Sievert J., The measurement of magnetic properties of electrical sheet steel –survey on method and situation of standards, J. Magn. Mag. Mat., 215-6 (2000) 647-651
  • [4] Lotten T. et al., A new Epstein frame for lamination core loss measurements at high frequencies and high flux densities, IEEE Trans Mag., (2006) 597-600
  • [5] Antonelli E. et al., Epstein Frame: How and when can it be reallyrepresentative about the magnetic behaviour of laminated magnetic steels, IEEE Trans. Mag., 41 (2005), no. 5, 1516- 1519
  • [6] Dieterly D. C., D-C permeability testing on Epstein samples with double lap joints, 51st Ann. Meeting of the AMST, Detroit, USA June 1948, publication 85
  • [7] Marketos P. et al., A method for defining the mean path length of the Epstein frame, IEEE Trans. Mag. 43 (2007) no. 6, 2755- 2757
  • [8] Moses A. J., Characterisation and performance of electrical steels for power transformers operating under extremes of magnetisation conditions, Cigre Int. Coll. Transformer Research and Asset Management, Cavtat, Croatia, 12-14th Nov. 2009
  • [9] Rogowski W. and Steinhause W., Measuring magnetic potential, Arch. Electrotech. 1 (1912) 141
  • [10] Mikulec M., AC compensated permeameter, Proc SMM3 Conf. Bratislava (1977) paper 19-3 669-670
  • [11] Khanlou A. et al., A computerized on-line power loss testing system for the steel industry, based on the RCP compensation technique, IEEE Trans. Mag., 31 (1993) no. 6, 3385-3387
  • [12] Zemanek I., Single sheet on-line testing based on the MMF compensation method, Przegląd Elektrotechniczny (Electrical Review), 85 (2009), no. 1, 79-83
  • [13] Tumanski S. and Baranowski S., Single strip tester of magnetic materials with array of magnetostrictive sensors, Przegląd Elektrotechniczny (Electrcial Review), 83 (2007), no. 4, 46-49
  • [14] Beckley P. et al., On-line, single sheet and Epstein power loss testing, J. Magn. Mag. Mat. 26 (1982) 168-175
  • [15] Moses A. J., Importance of rotational losses in rotating machines and transformers, J. Mat. Eng. and Performance, 1 (1992) no.2, 235-244
  • [16] Sievert J. et al., European intercomparison of measurements of rotational power loss in electrical sheet steel, J. Magn. Mag. Mat.160 (1996), 115-118
  • [17] Krismanic G., Recent development and trends in measurements of two-dimensional magnetic properties, J. Elect. Eng., 55 (12004) no. 10 45-48
  • [18] Moses A. J., The case for characterisation of rotational loss under pure rotational field conditions, Przegląd Elektrotechniczny 81 (2005), 1-4
  • [19] Moses A. J., Rotational magnetisation – problems in experimental and theoretical studies of electrical steels and amorphous magnetic materials, IEEE Trans. Mag. 30, (1994) no. 2 902-906
  • [20] Appino C. et al., Loss decomposition under two-dimensional flux loci in non-oriented steel sheets, Przegląd Elektrotechniczny (Electrical Review), 83 (2007) No. 4, 25-30
  • [21] Pfützner H., et al., A study on possible sources of errors of loss measurement under rotational magnetization, Przegląd Elektrotechniczny (Electrical Review), 83 (2007) No. 4, 9-14
  • [24] Lin Z. W. et al., Magnetic properties of soft magnetic composites under three-dimensional excitations, Int. J. Appl. Electromagnetics and Mechanics, 25 (2007) 237-241
  • [22] Ball D. A. and Lorch H. O., Thermal measurement of local power dissipation, J. Sci. Inst., 42 (1965) 90-93
  • [23] Ragusa C. et al., An intercomparison of rotational loss measurement in non-oriented Fe-Si alloys, J. Magn. Mag. Mat., 320 (2008) e623-626
  • [25] Yabumoto M., Review of techniques for measurement of magnetostriction in electrical steels and progress towards standardization, Przegląd Elektrotechniczny (Electrical Review), 85 (2009) No. 1, 1-6
  • [26] Enokizono M. et al., Measurement of dynamic magnetostriction under rotating magnetic field, IEEE Trans Mag. 26 (1990) no.5, 2067-9
  • [27] Hasenzagl B. el al., Magnetostriction of 3 % SiFe for 2- dmagnetization patterns, J. Magn, Mag. Mat. 160 (1996) 55-56
  • [28] Somkun S., Comparison of AC magnetostriction of nonoriented electrical steels measured in Epstein and disc samples, submitted to J. Elect. Eng. (2010)
  • [29] Layland N. et al., Effect of shape on samples of silicon-iron on the directions of magnetic field and flux density, Studies in Applied Electromagnetics and Mechanics 10, Non-linear Electromagnetic Systems, IOS Press (1996) 800-803
  • [30] Kiiskinen E., The effect of the D.C. component on the primary current and iron losses of distribution transformers, Sahko, 45 (1972), no 7-8, 329-332
  • [31] Mulasalihovic E. et al., Complete surface analysis of model transformer core considering dc-magnetization components, Przegląd Elektrotechniczny (Electrical Review), 85 (2009) No. 1, 43-46
  • [32] Mlejnek P. and Kaspar P., The phase displacement of dc tolerance current transformers under dc biasing, J. Elect. Eng., 59 (2008) no.7s, 94-96
  • [33] Marketos P. et al., Effect of DC excitation voltage on AC magnetisation of transformer core steel, submitted to J. Elect. Eng. (2010)
  • [34] Tamaki T. et al., Comparison of magnetic field analysis methods considering magnetic anisotropy, IEEE Trans. Mag., 46 (2010) no. 2, 187-190
  • [35] Okakazi Y. et al., Magnetic shielding by grain-oriented electriclal steel sheet under alternating fields up to 100kHz, Przegląd Elektrotechniczny (Electrical Review), 85 (2009), no. 1, 55-159
  • [36] Moses A. J. et al., Low frequency magnetic shielding: Present and future measurement, Przegląd Elektrotechniczny, 83 (2007) no. 4, 83-87
  • [37] Boglietti A. et al., Iron loss measurements with inverter supply: A first discussion to define a standard methodology, IEEE Trans. Mag., 31 (1995) no 6, 4006-8
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-PWA7-0051-0002
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