2022
DOI: 10.1109/access.2022.3226688
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Advanced Coordination Method for Overcurrent Protection Relays Using New Hybrid and Dynamic Tripping Characteristics for Microgrid

Abstract: Nowadays, the Overcurrent (OC) and Earth Fault (EF) relays coordination problem is one of the most complex and challenging concerns of power protection and network operators due to the high and volatile generation capacity of renewable energy sources in the grid. In this article, a new and dynamic optimal coordination scheme based on a novel hybrid tripping characteristic has been designed and developed for Over Current Relays (OCRs). Considering the impact of renewable energy sources such as the photovoltaic … Show more

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Cited by 10 publications
(5 citation statements)
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References 31 publications
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“…As the non-periodic components of the current decay, the three-phase current exhibits a sinusoidal symmetric waveform in a steady state. The calculated and simulated current amplitudes under steady-state conditions are 67.24 A and 65.5 A, respectively, with an error of 2.66%, which generally conforms to the current expression in Equation (25). The waveform of phase A fault current when a single-pole ground fault occurs in the DC sub-grid is shown in Figure 17.…”
Section: Simulation Analysissupporting
confidence: 65%
See 1 more Smart Citation
“…As the non-periodic components of the current decay, the three-phase current exhibits a sinusoidal symmetric waveform in a steady state. The calculated and simulated current amplitudes under steady-state conditions are 67.24 A and 65.5 A, respectively, with an error of 2.66%, which generally conforms to the current expression in Equation (25). The waveform of phase A fault current when a single-pole ground fault occurs in the DC sub-grid is shown in Figure 17.…”
Section: Simulation Analysissupporting
confidence: 65%
“…Furthermore, researchers are investigating fault current mitigation strategies that involve the coordination of protective devices [25][26][27][28], such as circuit breakers and fault detection systems, to improve the speed and accuracy of fault detection and isolation in DC sub-grid systems. Through integrating intelligent protection schemes and communication technologies, researchers aim to enhance the reliability and safety of hybrid AC/DC microgrid systems by effectively suppressing fault currents and minimizing the impact of DC grounding faults.…”
Section: Introductionmentioning
confidence: 99%
“…Research on short-circuit current flows (maximum and minimum) through the contribution of the power plant and the grid is used to adjust overcurrent protections (I>, I>>) in any configuration, ensuring the achievement of basic requirements set for each short-circuit protection and efficient separation under inappropriate conditions of parallel operation of the grid and the power plant [16][17].…”
Section: Protection Of Distribution Gridmentioning
confidence: 99%
“…, denoted as the discrimination margin time (DMT) or for a breaker-breaker scenario, is the combined result of , °, and , measured in seconds. As per IEEE-242, this interval is commonly approximated in research to fall within the range of 0.2 to 0.5 seconds [26].…”
Section: Relay Coordination Techniquesmentioning
confidence: 99%