An Artificial Neural Network Developed in MATLAB-Simulink for Reconstruction a Distorted Secondary Current Waveform. Part 1

Q3 Energy

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Pub Date : 2021-12-06 DOI:10.21122/1029-7448-2021-64-6-479-491

Y. Rumiantsev, F. Romaniuk

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引用次数: 2

Abstract

Recently, there has been an increased interest in the use of artificial neural networks in various branches of the electric power industry including relay protection. Аrtificial neural networks are one of the fastest growing areas in artificial intelligence technology. Recently, there has been an increased interest in the use of аrtificial neural networks in the electric power engineering, including relay protection. Existing microprocessor-based relay protection devices use a traditional digital signal processing of the monitored signals which is reduced to a multiplying the values of successive samples of the monitored current and voltage signals by predetermined coefficients in order to calculate their RMS values. In this case, the calculated RMS values often do not reflect the real processes occurring in the protected electrical equipment due to, for example, current transformer saturation because of the DC component presence in the fault current. When the current transformer is saturated, its secondary current waveform has a characteristic non-periodic distorted form, which is significantly differs from its primary (true) waveform, which causes underestimation of the calculated RMS value of the secondary current compared to its true value. In its turn, this causes to a trip time delay or even to a relay protection devices operation failure. The use of аrtificial neural networks in conjunction with a traditional digital signal processing provides a different approach to the functioning of both the measuring and logical parts of the microprocessor-based relay protection devices, which significantly increases the speed and reliability of such relay protection devices in comparison with their traditional implementation. A possible application of the аrtificial neural networks for the relay protection purposes is the fault occurrence detection and its type identification, current transformer secondary current waveform distortion restoration due to its saturation up to its true value, detection the distorted and undistorted sections of the current transformer secondary current waveform during its saturation, primary power equipment abnormal operating modes detection, for example, power transformer magnetizing current inrush. The article describes in detail the stages of the practical implementation of the аrtificial neural networks in the MATLAB-Simulink environment by the example of its use to restore the distorted current transformer secondary current waveform due to saturation.

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基于MATLAB-Simulink的人工神经网络重构二次电流畸变波形。第1部分

最近，在包括继电保护在内的电力工业的各个分支中使用人工神经网络的兴趣越来越大。Аrtificial神经网络是人工智能技术中发展最快的领域之一。最近，人们对在电力工程中使用人工神经网络越来越感兴趣，包括继电保护。现有的基于微处理器的继电保护装置对被监测信号采用传统的数字信号处理方法，将被监测电流和电压信号的连续采样值与预定系数相乘，从而计算出它们的均方根值。在这种情况下，计算的均方根值通常不能反映受保护电气设备中发生的真实过程，例如，由于故障电流中存在直流分量而导致的电流互感器饱和。当电流互感器饱和时，它的二次电流波形呈现出一种特征的非周期性畸变形式，与它的一次(真)波形明显不同，导致二次电流的计算均方根值与真值相比被低估。反过来，这会导致跳闸时间延迟甚至继电保护装置操作失败。将人工神经网络与传统的数字信号处理相结合，为基于微处理器的继电保护装置的测量和逻辑部分的功能提供了一种不同的方法，与传统的实现相比，这大大提高了此类继电保护装置的速度和可靠性。人工神经网络在继电保护中的一个可能的应用是故障发生检测及其类型识别，电流互感器二次电流波形因其饱和而失真恢复到其真值，电流互感器二次电流波形在其饱和时失真段和未失真段的检测，一次电力设备异常运行模式的检测，例如。电力变压器励磁涌流。本文详细介绍了人工神经网络在MATLAB-Simulink环境下实际实现的各个阶段，并以其用于恢复因饱和而失真的电流互感器二次电流波形为例。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations Energy-Nuclear Energy and Engineering

CiteScore

1.60

自引率

0.00%

发文量

审稿时长

8 weeks

期刊介绍： The most important objectives of the journal are the generalization of scientific and practical achievements in the field of power engineering, increase scientific and practical skills as researchers and industry representatives. Scientific concept publications include the publication of a modern national and international research and achievements in areas such as general energetic, electricity, thermal energy, construction, environmental issues energy, energy economy, etc. The journal publishes the results of basic research and the advanced achievements of practices aimed at improving the efficiency of the functioning of the energy sector, reduction of losses in electricity and heat networks, improving the reliability of electrical protection systems, the stability of the energetic complex, literature reviews on a wide range of energy issues.