Impact of the Cooling Equipment on the Key Design Parameters of a Core–Form Power Transformer

[1] Del VECCHIO, R. M.—POULIN, B.—FEGHALI, P. T.—SHAH, D. M.—AHUJA, R. : Transformer Design Principles: with Applications to Core-Form Power Transformers, CRC press, 2010.Search in Google Scholar

[2] RYAN, H. M. : High Voltage Engineering and Testing 3rd Edition. IET, 2013, N0 32.10.1049/PBPO066ESearch in Google Scholar

[3] KULKARNI, S. V.—KHAPARDE, S. : Transformer Engineering: Design and Practice. CRC Press, 2004,, vol. 25.10.1201/9780203970591Search in Google Scholar

[4] KAPP, G. : Transformatoren für Wechselstrom und Drehstrom (Transformers for Single and Multiphase Currents: A Treatise on Their Theory, Construction, and Use), Nabu Press, Charleston SC, United States, 2012.Search in Google Scholar

[5] ÚJHÁZY, G. : Erőátviteli transzformátorok gépi számításának kérdései (Application of Computers for Power Transformer Design), PhD dissertation, Budapest University of Technology and Economics, 1969. (In Hungarian)Search in Google Scholar

[6] JESZENSZKY, S. : History of Transformers, Power Engineering Review, IEEE 16 No. 12 (1996), 9.10.1109/MPER.1996.546444Search in Google Scholar

[7] IEEE Loss Evaluation Guide for Power Transformers and Reactors, IEEE IEEE Std C57 120, 1992.Search in Google Scholar

[8] GEORGILAKIS, P. S. : Environmental Cost of Distribution Transformer Losses, Applied Energy 88 No. 9 (2011), 3146-3155.10.1016/j.apenergy.2010.12.021Search in Google Scholar

[9] CORHODZIC, S.—KALAM, A. : Assessment of Distribution Transformers using Loss Capitalization Formulae, Journal of Electrical and Electronics Engineering Australia 20 No. 1 (2000), 43-48.Search in Google Scholar

[10] GEORGILAKIS, P.—AMOIRALIS, E. : Distribution Transformer Cost Evaluation Methodology Incorporating Environmental Cost, IET Generation, Transmission & Distribution 4 No. 7 (2010), 861-872.10.1049/iet-gtd.2009.0638Search in Google Scholar

[11] CHOWDHURY, A.—BERTLING, L.—CUSTER, D. : Determining Distribution Substation Transformer Optimal Loadings using a Reliability Cost-Benefit Approach, in International Conference on Probabilistic Methods Applied to Power Systems PMAPS 2006, IEEE, 2006, pp. 1-9.10.1109/PMAPS.2006.360426Search in Google Scholar

[12] OROSZ, T.—SŐRÉS, P.—RAISZ, D.—TAMUS, Á. Z. : Analysis of the Green Power Transition on Optimal Power Transformer Designs, Periodica Polytechnica Electrical Engineering and Computer Science 59 No. 3 (2015), 125-131.10.3311/PPee.8583Search in Google Scholar

[13] AMOIRALIS, E. I.—TSILI, M. A.—KLADAS, A. G. : Transformer Design and Optimization: a Literature Survey, Power Delivery, IEEE Transactions on 24 No. 4 (2009), 1999-2024.Search in Google Scholar

[14] KHATRI, A.—MALIK, H.—RAHI, O. : Optimal Design of Power Transformer using Genetic Algorithm, in Communication Systems and Network Technologies (CSNT), 2012 International Conference on, IEEE, 2012, pp. 830-833.10.1109/CSNT.2012.180Search in Google Scholar

[15] OLIVARES-GALVAN, J.—GEORGILAKIS, P.—FOFANA, I.—MAGDALENO-ADAME, S.—CAMPERO-LITTLEWOOD, E.—ESPARZA-GONZALEZ, M. : A Bibliographic Analysis of Transformer Literature 2001–2010.Search in Google Scholar

[16] AMOIRALIS, E. I.—TSILI, M. A.—GEORGILAKIS, P. S. : The State of the Art in Engineering Methods for Transformer Design and Optimization: a Survey, Journal of Optoelectronics and Advanced Materials 10 No. 5 (2008), 1149.Search in Google Scholar

[17] ABETTI, P.—CUTHBERTSON, W.—WILLIAMS, S. : Philosophy of Applying Digital Computers to the Design of Electric Apparatus, Transactions of the American Institute of Electrical Engineers, Part I: Communication and Electronics 77 No. 3 (1958), 367-379.Search in Google Scholar

[18] ANDERSEN, O. W. : Optimized Design of Electric Power Equipment, Computer Applications in Power, IEEE 4 No. 1 (1991), 11-15.Search in Google Scholar

[19] YADAV, A. K.—SINGH, A.—MALIK, H.—AZEEM, A. : Cost Analysis of Transformers Main Material Weight with Artificial Neural Network (ann), in Communication Systems and Network Technologies (CSNT), 2011 International Conference on, IEEE, 2011, pp. 184-187.10.1109/CSNT.2011.46Search in Google Scholar

[20] JABR, R. A. : Application of Geometric Programming to Transformer Design, Magnetics, IEEE Transactions on 41 No. 11 (2005), 4261-4269.Search in Google Scholar

[21] GEORGILAKIS, P. S. : Spotlight on Modern Transformer Design, Springer Science & Business Media, 2009.10.1007/978-1-84882-667-0Search in Google Scholar

[22] AMOIRALIS, E. I.—TSILI, M. A.—GEORGILAKIS, P. S.—KLADAS, A. G.—SOUFLARIS, A. T. : A Parallel Mixed Integer Programming-Finite Element Method Technique for Global Design Optimization of Power Transformers, IEEE Transactions on Magnetics 44 No. 6, 1022-1025 2008.10.1109/TMAG.2007.915119Search in Google Scholar

[23] TSIVGOULI, A. J.—TSILI, M. A.—KLADAS, A. G.—GEORGILAKIS, P. S.—SOUFLARIS, A. T.—SKARLATINI, A. D. : Geometry Optimization of Electric Shielding in Power Transformers based on Finite Element Method, Journal of Materials Processing Technology 181 No. 1 (2007), 159-164.10.1016/j.jmatprotec.2006.03.049Search in Google Scholar

[24] OROSZ, T.—SLEISZ, A.—VAJDA, I. : Core-Form Transformer Design Optimization with Branch and Bound Search and Geometric Programming, in Power and Electrical Engineering of Riga Technical University (RTUCON), 2014 55th International Scientific Conference on, IEEE, 2014, pp. 17-21.10.1109/RTUCON.2014.6998194Search in Google Scholar

[25] OROSZ, T.—SLEISZ, Á.—TAMUS, Z. : Meta-Heuristic Optimization Preliminary Design Process of Core-Form Autotransformers, IEEE Transaction on Magnetics 99 (2016).10.1109/TMAG.2015.2496905Search in Google Scholar

[26] BOYD, S.—VANDENBERGHE, L. : Convex Optimization, Cambridge University Press, 2004.10.1017/CBO9780511804441Search in Google Scholar

[27] BOYD, S.—KIM, S.-J.—VANDENBERGHE, L.—HASSIBI, A. : A Tutorial on Geometric Programming, Optimization and Engineering 8 No. 1 (2007), 67-127.10.1007/s11081-007-9001-7Search in Google Scholar

[28] ANDERSEN, M. S.—DAHL, J.—VANDENBERGHE, L. : CVXOPT: A Python Package for Convex Optimization, version 1.1.6, Available at cvxopt.org, 2013.Search in Google Scholar

[29] RYDER, S.—VAUGHAN, I. J. et al : A Simple Method for Calculating Core Temperature Rise in Power Transformers, Power Delivery, IEEE Transactions on 19 No. 2 (2004), 637-642.Search in Google Scholar

[30] GURU, B. S.—HIZIROGLU, H. R. : Electric Machinery and Transformers, vol. 726, Oxford University Press, New York, 2001.Search in Google Scholar

[31] KUCZMANN, M. : Using the NewtonRaphson Method in the Polarization Technique to Solve Nonlinear Static Magnetic Field Problems, Magnetics, IEEE Transactions on 46 No. 3 (2010), 875-879.Search in Google Scholar

[32] AK-Steel, TRAN-COR H Grain Oriented Electrical Steels, June 2013.Search in Google Scholar

[33] GROSSMANN, I. E. : Review of Nonlinear Mixed-Integer and Disjunctive Programming Techniques, Optimization and Engineering 3 No. 3 (2002), 227-252.10.1023/A:1021039126272Search in Google Scholar

[34] IEC Standard Power Transformers-Temperature Rise, Std. IEC Std 60 076-2, 1993.Search in Google Scholar

[35] EEE Standard General Requirements for Liquid-Immersed Distribution, Power, and Regulating Transformers, Std. IEEE Std. C57.12.00-2000, 2000.Search in Google Scholar

[36] KARSAI, K.—KERÉNYI, D.—KISS, L. : Large Power Transformers, Elsevier Science Pub. Co. Inc., New York, 1987.Search in Google Scholar