Customer loads connected to electricity supply systems may be broadly categorized as either linear or nonlinear. Nonlinear loads inject harmonics into the power network. Harmonics in a power system are classified as either load harmonics or as supply harmonics depending on their origin. The source impedance also impacts the harmonic current flowing in the network. Hence any change in the source impedance is reflected in the harmonic spectrum of the current. This paper proposes a novel method based on Artificial Neural Networks to isolate and evaluate the impact of the source impedance change without disrupting the operation of any load, by using actual field data. The test site chosen for this study has a significant amount of triplen harmonics in the current. By processing the acquired data with the proposed algorithm, the actual load harmonic contribution of the customer is predicted. Experimental results confirm that attempting to predict the total harmonic distortion (THD) of a customer by simply measuring the customer's current may not be accurate. The main advantage of this method is that only waveforms of voltages and currents at the point of common coupling have to be measured. This method is applicable for both single and three phase loads.
J. Mazumdar et al., "Intelligent Tool for Determining the True Harmonic Current Contribution of a Customer in a Power Distribution Network," Conference Record of the 41st IAS Annual Meeting of the Industry Applications Conference, 2006, Institute of Electrical and Electronics Engineers (IEEE), Jan 2006.
The definitive version is available at https://doi.org/10.1109/IAS.2006.256597
41st IAS Annual Meeting of the Industry Applications Conference, 2006
Electrical and Computer Engineering
Keywords and Phrases
Harmonic Analysis; Neural Networks; Power Quality; Power System Harmonics; Total Harmonic Distortion
International Standard Serial Number (ISSN)
Article - Conference proceedings
© 2006 Institute of Electrical and Electronics Engineers (IEEE), All rights reserved.
01 Jan 2006