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Abstract
This paper presents a procedure to estimate the impacts on voltage harmonic distortion at a point of interest due to multiple nonlinear loads in the electrical network. Despite artificial neural networks (ANN) being a widely used technique for the solution of a large amount and variety of issues in electric power systems, including harmonics modeling, its utilization to establish relationships among the harmonic voltage at a point of interest in the electric grid and the corresponding harmonic currents generated by nonlinear loads was not found in the literature, thus this innovative procedure is considered in this article. A simultaneous measurement campaign must be carried out in all nonlinear loads and at the point of interest for data acquisition to train and test the ANN model. A sensitivity analysis is proposed to establish the percent contribution of load currents on the observed voltage distortion, which constitutes an original definition presented in this paper. Initially, alternative transient program (ATP) simulations are used to calculate harmonic voltages at points of interest in an industrial test system due to nonlinear loads whose harmonic currents are known. The resulting impacts on voltage harmonic distortions obtained by the ATP simulations are taken as reference values to compare with those obtained by using the proposed procedure based on ANN. By comparing ATP results with those obtained by the ANN model, it is observed that the proposed methodology is able to classify correctly the impact degree of nonlinear load currents on voltage harmonic distortions at points of interest, as proposed in this paper.
Highlights
The increasing utilization of nonlinear loads in electrical systems is significantly producing harmonic distortions on voltage and currents, which are impacting electrical grid power quality
For designing the artificial neural networks (ANN) model, the database was divided into a training set, validation set, and test set, with 20% of samples used for testing, and 80% for the ANN training/validation step, which is divided into 80% for training and 20% for validation
The methodology is based on simultaneous measurements of voltage and current, and the application of artificial neural networks models to express the correlation between measured voltage at the grid and the corresponding nonlinear load current at the customer’s installation
Summary
The increasing utilization of nonlinear loads in electrical systems is significantly producing harmonic distortions on voltage and currents, which are impacting electrical grid power quality. It is the utility’s concern to continuously monitor its electrical grid, aiming at detecting suspicious loads that may be contributing to the voltage harmonic distortion above specified limits, observed at some specific locations of interest. To illustrate the complexity of this analysis, suppose four industrial customers are being supplied by the same feeder, and the grid voltage harmonic distortion is within the specified limits Considering this scenario, let us suppose a new customer is connected to the same feeder as the four former ones. It is necessary to carry out another joint analysis to determine the new impacts of each customer in this new scenario
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