Abstract
Lithium batteries are used for frequency regulation in power systems because of their fast response and high efficiency. Lithium batteries have different life characteristics depending on their type, and it is necessary to set the optimal state-of-charge (SOC) operating range considering these characteristics to obtain the maximum gain. In general, narrowing the operating range increases the service life but may lower the performance of charging and discharging operations in response to frequency fluctuations, and vice versa. We present performance assessment indicators that consider charging and discharging due to frequency variations and lifespan of the batteries. However, to evaluate the performance, while reflecting the non-linear life characteristics of lithium batteries, simulating the entire operation is necessary, which requires a long calculation time. Therefore, we propose a master–slave parallel genetic algorithm to derive the optimal SOC operating range with reduced calculation time. A simulation program was implemented to evaluate the computational performance that determines the optimal SOC range. The proposed method reduces the calculation time while considering the non-linear life characteristics of lithium batteries. It was confirmed that a more accurate SOC operating range could be calculated by simulating the entire life span.
Highlights
A power system must maintain a balance between power generation and load to sustain a stable frequency
We proposed a method for setting optimal SOC operating range of the energy storage system for frequency regulation (ESS-FR), considering the nonlinear life model of a lithium battery
The operation of the energy storage system used for frequency regulation was formulated and summarized
Summary
A power system must maintain a balance between power generation and load to sustain a stable frequency. In a rotary power system, the rotational speed of the generator increases as the load decreases, and vice versa This balance is altered by changes in the power system frequency. The second is to control the output fluctuations by measuring the frequency in the energy management system (EMS) that operates the power system and communicates with the generator or energy storage device considering the cost and efficiency of the output from each generator. This is called secondary frequency control (SFC) or automatic generation control (AGC)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
