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Principles of Current Protection Based on Three Instantaneous-Value Samples

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N. Burianina; E. Lesnykh; K. Suslov
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Abstract:

The paper proposes equations for finding the current parametric values and their derivatives based on three samples. These equations reduce the effect of non-periodic com...Show More

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Abstract:

The paper proposes equations for finding the current parametric values and their derivatives based on three samples. These equations reduce the effect of non-periodic components on how accurately their periodic counterparts are isolated from the current samples received by digital power-system protection devices. No calculation errors occur when parameters are sinusoidal. We have developed an algorithm to correct current data when the current transformers have their magnetic cores saturated.
Published in: 2018 International Conference on Industrial Engineering, Applications and Manufacturing (ICIEAM)
Date of Conference: 15-18 May 2018
Date Added to IEEE Xplore: 06 June 2019
ISBN Information:
DOI: 10.1109/ICIEAM.2018.8728871
Conference Location: Moscow, Russia
References is not available for this document.
Contents

I. Introduction

Computational devices used to control power facilities fall into two groups: those for slow (seconds-long)processes and those for fast (milliseconds-long)processes. The latter include power-system protection (PSP)and fault localization (FL), whereby faults include short circuits (SC)and open-phase faults. In case of FL, SC can be eliminated as a part of the automatic re-activation cycle; or the line can be switched off for a longer period until a repair team handles the fault. Given that SC have to be switched off within two or three frequency periods, PSP should operate within one or two periods. Thus, emergency control algorithms have to meet very stringent requirements. In such cases, we need algorithms that non-industrial-frequency currents and voltages can't interfere with. Modern digital PSP algorithms are triggered after analog or digital filtering is complete [1]–[3]. Filtering undergoes the transient-response stage, which is time-consuming. This is especially true when it comes to filtering such SC currents that contain both periodic and non-periodic components. Dev-proposed PSP provide for a protection delay for at least one period [1], [4]. The situation is exacerbated by the possible saturation of current-transformer magnetic cores. Saturation-induced errors and other errors can be reduced by means of least squares [5], [6] or by discrete Fourier transformation [7]–[11]. Cosine filters are often used in microprocessor protection [10]–[15]. Cosine filters are practically insensitive to non-periodic components. However, these methods take long to implement. This is why it is important to develop algorithms capable of isolating the sinusoidal components within half a period or less. This is what our research is about.

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