Abstract
As the penetration of renewable energy sources (RESs) increases, the rate of conventional generators and the power system inertia are reduced accordingly, resulting in frequency-stability concerns. As one of the solutions, the battery-type energy storage system (ESS), which can rapidly charge and discharge energy, is utilized for frequency regulation. Typically, it is based on response-driven frequency control (RDFC), which adjusts its output according to the measured frequency. In contrast, event-driven frequency control (EDFC) involves a determined frequency support scheme corresponding to a particular event. EDFC has the advantage that control action is promptly performed compared to RDFC. This study proposes an ESS EDFC strategy that involves estimating the required operating point of the ESS according to a specific disturbance through neural-network training. When a disturbance occurs, the neural networks can estimate the proper magnitude and duration of the ESS output to comply with the frequency grid code. A simulation to validate the proposed control method was performed for an IEEE 39 bus system. The simulation results indicate that a neural-network estimation offers sufficient accuracy for practical use, and frequency response can be adjusted as intended by the system operator.
Highlights
The power systems of the world have been changing significantly, as the penetration of renewable energy sources (RESs) has accelerated
When energy storage system (ESS) outputs the power that is proportional to the rate of change of the frequency (ROCOF), it can operate as a virtual synchronous machine (VSM)
The neural networks were trained with a dataset consisting of numerous examples according to the disturbance in the system
Summary
The power systems of the world have been changing significantly, as the penetration of renewable energy sources (RESs) has accelerated. When ESS outputs the power that is proportional to the rate of change of the frequency (ROCOF), it can operate as a VSM. Since ESSs with flexible power control are suitable for RDFC, EDFC is generally not used by ESSs. EDFC has been studied in the field of under-frequency load shedding (UFLS) [19,20,21]. If the frequency can remain stable even when the ESS stops the control action after a certain duration, there is no need for ESSs to maintain the output. The frequency-response characteristics of the power system are highly nonlinear, they can be learned by a neural network It can determine whether the ESSs should maintain the output or not according to frequency measurements in a short time.
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