High frequency transformer model derived from limited information about the transformer geometry

High frequency transformer model derived from limited information about the transformer geometry

•Transformer model based on limited information about the transformer geometry.•Complex permeability equivalence principle.•Transformer nodal frequency dependence admittance matrix.•Verification based on lightning impulse tests measurements. To represent transformer behaviour during a transient stat...

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Bibliographic Details
Published in:International journal of electrical power & energy systems Vol. 94; pp. 300 - 310
Main Authors: Jurisic, Bruno, Uglesic, Ivo, Xemard, Alain, Paladian, Françoise
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-01-2018
Subjects:
Complex permeability
Fitting
Grey Box
Passivity enforcement
Transformer modelling
Grey Box
Passivity enforcement
Complex permeability
Transformer modelling
Fitting
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Summary:•Transformer model based on limited information about the transformer geometry.•Complex permeability equivalence principle.•Transformer nodal frequency dependence admittance matrix.•Verification based on lightning impulse tests measurements. To represent transformer behaviour during a transient state which includes high frequencies, it is necessary to consider the resonances which occur inside the transformer. One strategy is to deduce the transformer model from the measurements of the transformer’s frequency response, another one is to construct the model based on a careful representation of the inside of the apparatus. In the paper a model is presented which is compatible with EMTP-type software programs based on a finite element method (FEM) calculations and the complex permeability approximation. The model can be classified as a Grey Box transformer model, according to the terminology of the CIGRE. The model’s frequency dependent parameters are derived from limited information about the transformer geometry. State space equations are used to input the model into an electromagnetic transient calculation software program. This approach requires specific mathematical treatments to avoid stability issues during simulations. The model is validated for lightning impulse studies using the field test measurements of over-voltages that had occurred at the external transformer’s terminals.
ISSN:0142-0615
1879-3517
DOI:10.1016/j.ijepes.2017.07.017