Abstract
The optimal coordination of overcurrent relays (OCRs) has recently become a major challenge owing to the ever-increasing participation of distributed generation (DG) and the multi-looped structure of modern distribution networks (DNs). Furthermore, the changeable operational topologies of microgrids has increased the complexity and computational burden to obtain the optimal settings of OCRs. In this context, classical approaches to OCR coordination might no longer be sufficient to provide a reliable performance of microgrids both in the islanded and grid-connected operational modes. This paper proposes a novel approach for optimal coordination of directional OCRs in microgrids. This approach consists of considering the upper limit of the plug setting multiplier (PSM) as a variable instead of a fixed parameter as usually done in traditional approaches for OCRs coordination. A genetic algorithm (GA) was implemented to optimize the limits of the maximum PSM for the OCRs coordination. Several tests were performed with an IEC microgrid benchmark network considering several operational modes. Results showed the applicability and effectiveness of the proposed approach. A comparison with other studies reported in the specialized literature is provided showing the advantages of the proposed approach.
Highlights
The proliferation of small-scale rotary machines and distributed generation (DG) units within distribution networks (DNs) has brought new opportunities in the diversification of the energy basket and a better use of natural resources which promotes sustainability
In the first operational mode, the DG units are disconnected from the microgrid and the load is supplied through the main grid
The microgrid is operating in islanded mode and the load is supplied by the DG units
Summary
The proliferation of small-scale rotary machines and distributed generation (DG) units within distribution networks (DNs) has brought new opportunities in the diversification of the energy basket and a better use of natural resources which promotes sustainability. The high penetration of DG causes bidirectional power flows and currents that change the traditional dynamic interaction between loads and generators [1,2,3,4]. Such interaction makes the problem of protection coordination even more complex. Protection systems in microgrids must deal with the following two aspects: (a) the dynamic behavior that is usually presented due to intermittent energy resources and (b) the microgrid operation mode which can be connected or disconnected from the main power grid [5,6]. Microgrids are reconfigurable electric power systems with variable levels of current fault and bidirectional power flows [7]. Microgrids have changed the traditional paradigm of radial DNs into non-radial and flexible
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