МУЛЬТИФИЗИЧЕСКОЕ МОДЕЛИРОВАНИЕ ЭЛЕКТРОТЕХНИЧЕСКИХ УСТРОЙСТВ
ARTICLE_1_PDF

Ключові слова

multiphysics modeling
multi-field problems
multiphysics circuits
field-circuit problems
strong and weak coupled processes мультифизическое моделирование
мультиполевые задачи
мультифизические цепи
цепно-полевые задачи
сильно- и слабосвязанные процессы

Як цитувати

[1]
Подольцев, А. і Кучерявая, И. 2015. МУЛЬТИФИЗИЧЕСКОЕ МОДЕЛИРОВАНИЕ ЭЛЕКТРОТЕХНИЧЕСКИХ УСТРОЙСТВ. ТЕХНІЧНА ЕЛЕКТРОДИНАМІКА. 2 (Бер 2015), 003.

Анотація

В работе дана общая характеристика моделирования электротехнических устройств с одновременно протекающими процессами различной физической природы – мультифизического моделирования. Проведена классификация мультифизических задач в электротехнике как по характеру связи между такими физическими процессами, так и по подходам к их моделированию. В соответствии с такой классификацией выполнен обзор литературных источников и приведены примеры решения трех типов мультифизических задач. Библ. 42, рис. 7, табл. 2.

ARTICLE_1_PDF

Посилання

Vaskovskii Yu.N. Perspectives for modeling of electromechanical converts under dynamic conditions on the basis of field-circuit methods // Elektrotekhnika i Elektromekhanika. – 2003. – № 1. – Pp. 23–25. (Rus)

Glukhenkyi A.I., Gorislavets Yu.M. Scalar electric and vector magnetic potentials in the theory of electromagnetic field // Tekhnichna Elektrodynamika. – 2012. – № 2. – Pp. 7–8. (Rus)

Glukhenkyi A.I., Gorislavets Yu.M., Maksimenko V.Yu. Electromagnetic stirrer of liquid metal with alternated action of traveling and pulsating magnetic fields // Tekhnichna Elektrodynamika. – 2014. – № 4. – Pp. 123–125. (Rus)

Demirchian K.S., Neiman L.R., Korovkin N.V., Chechurin B.L. Theoretical foundations of electrical engineering. Vol. 1. – Sankt-Peterburg: Piter, 2004. – 462 p. (Rus)

Korovkin N.V., Shishigin S.L. Computational methods in the theory of grounding // Nauchno-tekhnicheskie vedomosti Sankt-Peterburgskogo gosudarstvennogo politekhnicheskogo universiteta. – 2013. – № 1. – С. 74–79. – available at: http://ntv.spbstu.ru/fulltext/N1.166.2013_11.PDF. (accessed 5 August 2014). (Rus)

Kucheriavaia I.N. Application of multiscale modeling for study of electric field in insulation of 330 kV power cable at emergency operation // Tekhnichna Elektrodynamika. – 2012. – № 4. – Pp. 13–18. (Rus)

Lebedev V.D., Yablokov A.A. Study of dynamic processes in instrument current and voltage transformers // Vestnik IGEU. – 2013. – Is. 6. – Pp. 1–7. – http://vestnik.ispu.ru/sites/vestnik.ispu.ru/files/ publications/str.98-104.pdf. (Rus)

Mathematical modeling and realization of full-scale experiment / Pod red. V.N.Timofeeva, E.A.Golovenko, E.V.Kuznetsova. – Krasnoiarsk: Sibirskii federalnyj universitet, 2007. – 210 p. (Rus)

Podoltsev A.D., Kucheriavaia I.N. Numerical calculation of electromagnetic and thermal processes in underground power cable line. Steady-state conditions. // Tekhnichna Elektrodynamika. Temat. vypusk "Sylova elektronika ta enerhoefektyvnist". – 2006. – Vol. 1. – Pp. 91–95. (Rus)

Rymsha V.V., Radimov I.N., Gulyi M.V., Kravchenko P.A. Improved field-circuit model of rectifierreluctance motor // Elektrotekhnika i Elektromekhanika. – 2010. – № 5. – Pp. 22–26. (Rus)

Segerlind L. Application of finite-element method. – Moskva: Mir, 1979. – 312 p. (Rus)

Shcherba A.A., Podoltsev A.D., Kucheriavaia I.N. Electromagnetic processes in 330 kV cable line with polyethylene insulation // Tekhnichna elektrodynamika. – 2013. – № 1. – Pp. 9–15. (Rus)

Shcherba A.A., Podoltsev A.D., Kucheriavaia I.N., Ushakov V.I. Computer modeling of electrothermal processes and thermomechanical stress at induction heating of moving copper ingots // Tekhnichna Elektrodynamika. – 2013. – № 2. – Pp. 10–18. (Rus)

Ansys Multiphysics – available at: http:// www.ansys.com (accessed 5 August 2014).

Bhide R.S., Kumbhar G.B., Kulkarni S.V., Koria J.P. Coupled circuit-field formulation for analysis of parallel operation of converters with interphase transformer // Electric Power Systems Research. – 2008. – Vol. 78. – Is. 1. – Pp. 158–164.

Chan T.F., Lai L.L., Yan L.T. A coupled circuit and field analysis of a three-phase induction motor with the Smith connection // IEEE Trans. on Magnetics. – 2006. – Vol. 42. – No. 4. – Pp. 1315–1318.

Сomsol Multiphysics – available at: http://www.comsol.com (accessed 5 August 2014).

Costa M.C., Nabeta S.I., Cardoso J.R. Modified nodal analysis applied to electric circuits coupled with FEM in the simulation of a universal motor // IEEE Trans. on Magnetics. – 2000. – Vol. 36. – No. 4. – Pp. 1431–1434.

Dular P. Dual magnetodynamic finite element formulations with natural definitions of global quantities for electric circuit coupling // Scientific Computing in Electrical Engineering. – 2001. – Vol. 18. – Pp. 367–377.

Eustache P., Meunier G., Coulomb J.L. Finite element toolbox for generic coupling (magnetic, thermal, etc.) // IEEE Trans. on Magnetics. – 1996. – Vol. 32. – Is. 3. – Pp. 1461–1464.

Gersem H., Hameyer K., Weiland T. Field-circuit coupled models in electromagnetic simulation // Journal of Computational and Applied Mathematics. – 2004. – Vol. 168. – Is. 1–2. – Pp. 125–133.

Gersem H., Mertens R., Lahaye D., Vandewalle S., Hameyer K. Solution strategies for transient, fieldcircuit coupled systems // IEEE Trans. on Magnetics. – 2000. – Vol. 36. – No. 4. – Pp. 1531–1534.

Golosnoy I.O., Sykulski J.K. Numerical modeling of non-linear coupled thermo-electric problems. A comparative study // The Internat. Journal for Computation and Mathematics in Electrical and Electronic Engineering (COMPEL). – 2009. – Vol. 28. – No. 3. – Pp. 639–655.

Hameyer K., Driesen J. , De Gersem H., Belmans R. The classification of coupled field problems // IEEE Trans. on Magnetics. – 1999. – Vol. 35. – No. 3. – Pp. 1618–1621.

Kanerva S. Simulation of electrical machines circuits and control systems using finite element method and system simulator // Doctoral Dissertation. – Helsinki University of Technology. Department of Electrical and Communications Engineering. – Helsinki, 2005. – 92 p. – available at: http://lib.tkk.fi/Diss/2005/isbn9512276100/isbn9512276100.pdf (accessed 5 August 2014).

Kulkarni S.V., Khaparde S.A. Transformer Engineering: Design, Technology, and Diagnostics. – CRC

Press, Taylor & Francis group, 2012. – 750 p.

Kumbhar G.B., Kulkarni S.V., Escarela-Perez R., Campero-Littlewood E. Applications of coupled field formulations to electrical machinery // The Internat. Journal for Computation and Mathematics in Electrical and Electronic Engineering (COMPEL). – 2007. – Vol. 26. – Is. 2. – Pp. 489–523.

Kumbhar G.B., Kulkarni S.V., Jochi V.S. Analysis of short circuit performance of split-winding transformer using coupled field-circuit approach // IEEE Trans. on Power Delivery. – 2007. – Vol. 22. – No. 2. – Pp. 936–943.

Manot G., Lefevre Y., Piquet H., Richardeau F. Integration of control loops in coupled field circuit model to study magnetic devices supplied by power electronic converter and their control // The Internat. Journal for Computation and Mathematics in Electrical and Electronic Engineering (COMPEL) – 2002. – Vol. 21. – No. 4. – Pp. 563–572.

Matlab. The Language of Technical Computing – available at: http://www.mathworks.com/ products/ matlab/ (accessed 5 August 2014).

Michopoulos J.G., Farhat С., Fish J. Survey on modeling and simulation of multiphysics systems. – 2005. – available at: http://www.columbia.edu/cu/civileng/fish/Publications_files/ MultiphysicsSurvey.pdf (accessed 5 August 2014).

Ortiz J.L.R., Sadowski N., Kuo-Peng P., Batistela N.J., Bastos J.P.A. Coupling static converter with control loop and nonlinear electromagnetic devices // IEEE Trans. on Magnetics. – 2001. – Vol. 37. – No. 5. – Pp. 3514–3517.

Simulink. Simulation and Model-Based Design. – available at: http://www.mathworks.com/ products/

simulink/ (accessed 5 August 2014).

Sykulski J.K. Computational magnetics. – Chapman & Hall Publisher, 1995. – 373 p.

Tanaka T., Takahashi N. Direct finite element analysis of flux and current distributions under specified conditions // IEEE Trans. on Magnetics. – 1990. – Vol. 26. – No. 2. – Pp. 968–970.

Tsukerman I.A., Konrad A., Meunier G., Sabonnadiere J.C. Coupled field-circuit problems: trends and accomplishments // IEEE Trans. on Magnetics. – 1993. – Vol. 29. – No. 2. – Pp. 1701–1704.

Turowski J. Coupled fields. − Springer, 1995. – Pp. 234–284.

Turowski J. Fast computation of coupled fields in complex, 3-D, industrial electromagnetic structures // The International Journal for Computation and Mathematics in Electrical and Electronic Engineering (COMPEL). – 1997. – Vol. 17. – No.4. – Pp. 489–505.

Vaananen J. Circuit theoretical approach to couple two-dimensional finite element model with external circuit equations // IEEE Trans. on Magnetics. – 1996. – Vol. 32. – No. 2. – Pp. 400–410.

Yatchev I. Coupled filed problems in electrical apparatus // Facta Universitatis. – 2003. – Vol. 3, No. 15. – Pp. 1089–1101. – available at: http://facta.junis.ni.ac.rs/macar/macar200303/ macar200303-15.pdf (accessed 5 August 2014).

Zhang Y., Zhang N., Kang Y., Yan X., Xie D. Magnetic field of a complex construction transformer using direct field-circuit coupling method // Advanced Materials Research. – 2013. – Vols. 614–615. – Pp. 1230–1233.

Zhou P., Fu W.N., Lin D., Stanton S., Cendes Z.J. Numerical modeling of magnetic devices // IEEE Trans. on Magnetics. – 2004. – Vol. 40. – No. 4. – Pp. 1803–1809.

Creative Commons License

Ця робота ліцензується відповідно до Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Авторське право (c) 2022 Array

Переглядів анотації: 31 | Завантажень PDF: 5

Завантаження

Дані завантаження ще не доступні.