Achieving the exact equivalent circuit of a large-scale transformer winding using an improved detailed model for partial discharge study

•A generalized state-space algorithm for PD studies in transformer winding is developed.•High matching of measured and simulated responses at wide frequency range is achieved.•FEM for accurate calculation of equivalent circuit parameters is employed.•Modeling of layer and disk windings and PD signal...

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Bibliographic Details
Published in:International journal of electrical power & energy systems 2022-01, Vol.134, p.107451, Article 107451
Main Authors: Rezaei Baravati, Peyman, Moazzami, Majid, Mohammad Hassan Hosseini, Seyed, Reza Mirzaei, Hassan, Fani, Bahador
Format: Article
Language:English
Subjects:
Detailed model
Equations of state-space
Finite element analysis
Modeling
Partial discharge (PD)
Transformers
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Summary:•A generalized state-space algorithm for PD studies in transformer winding is developed.•High matching of measured and simulated responses at wide frequency range is achieved.•FEM for accurate calculation of equivalent circuit parameters is employed.•Modeling of layer and disk windings and PD signal propagation is presented.•The proposed method improved frequency validity range (100 kHz ≤ f ≤ 5 MHz). Investigating partial discharge (PD) is a critical issue in monitoring the condition of power transformers. For analyzing the transient state behavior of transformer winding, the availability of a model that accurately presents its behavior at high frequencies is necessary. The conventional detailed model is among the models used to perform PD studies. One of the underlying issues of the conventional detailed model is the low frequency validity range of the model, which is limited to about 1 MHz. In this paper, an improved detailed model is presented that overcomes the mentioned problem by adding stray capacitances to the conventional detailed model. A general state-space algorithm is proposed to calculate the reaction of the winding towards the application of the PD signal. In the present study, the frequency-dependent parameters of the improved detailed model have been calculated via the finite element method (FEM). The new methods and ideas are implemented and validated on a real 20 kV distribution transformer winding as well as a 63 kV, 30MV winding. Comparing the results of the proposed model with the waveforms obtained from using PD pulses to both windings in the laboratory environment shows the accuracy and the increased frequency validity range of this model.
ISSN:0142-0615
DOI:10.1016/j.ijepes.2021.107451