Abstract—The scientific and methodological principles of development of the design models of a new device—station service voltage transformers intended for use in design study—are considered. The proposed models relate to the “white box” model class, which provide the maximum accuracy when solving such problems. The models are based on equivalent circuits of active parts, which are obtained using the principle of duality of magnetic and electric circuits. It is revealed that the determination of parameters and verification of models are possible only at the manufacturing plant of transformers. Special attention is paid to reproduction in the models of magnetizing process of transformer. The experimental oscillograms are given of magnetizing currents of magnetic conductors of the active parts and of the transformers as an assembly, which show the capacitances of high-voltage winding have a great effect on the open-circuit current. The algorithm for determination of the parameters of transformer model for calculation of steady state conditions is presented, which provides a good coincidence with experimental values for integral parameters, such as the power loss and the root-mean-square value of magnetizing current.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
REFERENCES
STO 56947007-29.240.10.248-2017. Normy tekhnologicheskogo proektirovaniya podstantsii peremennogo toka s vysshim napryazheniem 35–750 kV (STO 56947007-29.240.10.248-2017: Standards of Technological Design of AC Substations with Higher Voltage 35–750 kV), Moscow, 2017.
STO 56947007-29.240.40.263-2018. Sistemy sobstvennykh nuzhd podstantsii. Tipovye proektnye resheniya (STO 56947007-29.240.40.263-2018: Systems of Own Needs of Substations, Standard Design Solutions), Moscow, 2018.
Gustavsen, B., Wideband transformer modeling including core nonlinear effects, IEEE Trans. Power Delivery, 2016, vol. 31, no. 1.
Colin Cherry, E., The duality of interlinked electric and magnetic circuits and the formation of transformer equivalent circuits, Proc. Phys. Soc., London, Sect. B, 1949, vol. 62, no. 2.
Leites, L.V. and Pintsov, A.M., Skhemy zameshcheniya mnogoobmotochnykh transformatorov (Substitution Schemes of Multiwinding Power Converters), Moscow: Energiya, 1974.
Zikherman, M.Kh., Scattering in power converters, Energoekspert, 2014, no. 6.
Zhuikov, A.V., Kubatkin, M.A., Larin, V.S., Matveev, D.A., Nikulov, I.I., and Khrenov, S.I., Scattering inductances of transformer windings, Elektrotekhnika, 2019, no. 8.
Zirka, S.E., Moroz, Yu.I., Chiesa, N., Harrison, R.G., and Høidalen, H.Kr., Implementation of inverse hysteresis model into EMTP—Part I: Static model, IEEE Trans. Power Delivery, 2015, vol. 30, no. 5.
Zirka, S.E., Moroz, Yu.I., Chiesa, N., Harrison, R.G., and Høidalen, H.Kr., Implementation of inverse hysteresis model into EMTP—Part II: Dynamic model, IEEE Trans. Power Delivery, 2015, vol. 30, no. 5.
Funding
This work was financially supported by the Ministry of Education and Science of the Russian Federation, unique agreement identifier RFMEFI57717X0243.
Author information
Authors and Affiliations
Corresponding author
Additional information
Translated by M. Kromin
About this article
Cite this article
Zhuikov, A.V., Kubatkin, M.A., Larin, V.S. et al. Using Dual Circuits to Simulate Electromagnetic Processes in Cascade Station Service Voltage Transformers. Russ. Electr. Engin. 90, 579–584 (2019). https://doi.org/10.3103/S1068371219080121
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.3103/S1068371219080121