用于布置电池储能系统以提高电网暂态稳定性的分层优化技术

Energy Storage Pub Date : 2024-06-14 DOI:10.1002/est2.659
Sabrina Shams, Abdul H. Chowdhury, Md. Minarul Islam, Md. Shafiullah, Taha S. Ustun, Samsun Nahar, Kashem M. Muttaqi, Danny Sutanto
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引用次数: 0

摘要

电池储能系统(BESS)具有极快的动态响应速度,在改善电网瞬态频率稳定性方面发挥着至关重要的作用。BESS 的性能随系统安装地点的不同而变化。因此,BESS 的最佳安装位置对于提高瞬态频率稳定性至关重要。因此,本文提出了一种优化 BESS 位置的分层方法,以改善电网的瞬态频率稳定性。在大多数研究中,频率最低点和频率变化率(ROCOF)都被用来研究频率稳定性。本文在研究频率稳定度、沉降时间和衰减率时,还考虑了频率下限和频率变化率这两个参数。利用四个瞬态频率参数开发了一种新的频率稳定指数(FSI)。在基准测试系统中发生重大扰动后,频率稳定指数被用来确定 BESS 的最佳位置,以稳定频率。结果表明,在发电机突然停电后,当 BESS 位于最靠近停电发电机的母线上时,ROCOF 和频率低点的改善效果最好。然而,考虑到其他两个参数,FSI 的值也是最小的;也就是说,当 BESS 位于距离发生停电的发电机第二近的母线时,才是最佳解决方案。类似研究的结果验证了所提出的 FSI 值,该值可指示 BESS 的最佳位置,从而改善系统的瞬态频率行为。
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A hierarchical optimization technique for placement of battery energy storage system to improve grid transient stability

A battery energy storage system (BESS), due to its very fast dynamic response, plays an essential role in improving the transient frequency stability of a grid. The performance of the BESS varies with the system's installation site. Hence, the optimal location of the BESS is of utmost importance for improving transient frequency stability. Therefore, this paper presents a hierarchical approach for optimizing the BESS placement to improve a grid's transient frequency stability. In most research, frequency nadir and rate of change of frequency (ROCOF) have been considered for studying frequency stability. This paper considers two more parameters, along with frequency nadir and ROCOF, to study the transient frequency stability, settling time, and decay ratio. A novel frequency stability index (FSI) using the four transient frequency parameters has been developed. After a significant disturbance in a benchmarked test system, the FSI was used to identify the optimal location of the BESS for stabilizing the frequency. It has been observed that, after a sudden generator outage, the ROCOF and the frequency nadir improve the best when the BESS is located at the bus closest to the generator experiencing the outage. However, considering the other two parameters as well, the value of the FSI is the minimum; that is, the optimum solution is when the BESS is located at the bus that is the second closest to the generator experiencing the outage. Results of similar studies validate the proposed FSI in indicating the optimal location of the BESS in improving the transient frequency behavior of the system.

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