In order to meet the demand of power grid regulation, this paper proposes an optimal control method for large-scale battery energy storage to suppress the disturbance of power grid. According to the balance relationship among grid frequency, voltage, active power and reactive power, this paper firstly establishes a power control model of large-scale battery energy storage system considering the battery state of charge constraints. The control model includes measurement filtering, gain, dead zone, control and other complete links. On this basis, the frequency-modulation and voltage-regulation control model of large-scale battery energy storage suitable for grid regulation is derived. According to the regulation requirements of power grid and battery energy storage system with different capacity, the improved response-curve method is applied to optimize the control parameters in the model, so as to improve the flexibility and adaptability of the control system. Software PSASP is used to verify the effectiveness of the optimal control method of large-scale battery energy storage to suppress the disturbance of power grid. The results show that the system frequency can be controlled between 49.8~50.2 Hz and the bus voltage can be controlled between UN±10%UN using the proposed power control method when the grid frequency and voltage are abnormal due to large power disturbance.
Key words
battery energy storage /
frequency and voltage regulation /
transfer function /
control model
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References
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Funding
This work is supported by State Grid Corporation of China Research Program(No. DG71-17-012).
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