Abstract
Currently, active networks called microgrids are formed on the basis of local power supply systems with a small share of distributed generation. Microgrids operating in an island mode, in some cases, have the ability to transfer electricity excess to an external network leading to a synchronization requirement; thus, the optimization task in terms of the system’s synchronization must be considered. This paper proposes a method for obtaining synchronization between microgrids and power systems of limited capacity based on a passive synchronization algorithm, allowing us to connect a microgrid to an external power system with a minimum impact moment on the shaft of the generating equipment. The algorithm application was demonstrated by considering a real-life object in Tajikistan. The simulation was carried out on RastrWin3. The obtained results show that the microgrid generator is connected to an external power system at an angle of 0.3° and a power surge of 29 kW, unlike the classical synchronization algorithm with an angle of 6.8° and a power surge of 154 kW (a reduction of the shock moment by more than five times). The proposed synchronization method allows us to reduce the resource consumption of the generating equipment and increase the reliability and efficiency of the functioning units of the examined power system.
Highlights
Nowadays, the traditional electricity grid has been transformed into smart infrastructure
The inclusion of power plant generators for parallel operation with the power system requires the fulfillment of synchronization conditions [20]
A simulation was performed for the power supply scheme for consumers in the mountainous area of Shujand, Rushan Region, Gorno-Badakhshan Autonomous Region (GBAR) in Tajikistan
Summary
The traditional electricity grid has been transformed into smart infrastructure. The main driving force is related to the integration of renewable energy sources (RESs) at both transmission and distribution levels. The distribution network requires to be more “smartness” since it implements a transformation from passive to active networks in terms of power flow direction (bidirectional), decision, control, and protection functions (distributed). When the distribution network functions under real-time conditions, the power generation should match consumer demands. To realize such a service, new system concepts are required. Microgrid systems are considered one of the optimal, beneficial, and practically realized solutions available since they incorporate different RESs with energy storage options [1,2,3,4,5,6]
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