考虑动态频率安全与N-k故障的鲁棒应急调度方法

doi:10.16182/j.issn1004731x.joss.25-0572

摘要/Abstract

摘要：

为解决高比例新能源并网以及机组故障共同导致的系统惯量缺失与频率失稳风险，提出了一种计及动态频率安全约束的N-k鲁棒应急调度方法。考虑变速抽水蓄能的频率响应特性，构建包含变速抽蓄的动态频率响应模型，并通过二阶锥转化建立频率最低点约束；采用信息熵理论量化机组故障的不确定性，构建考虑机组N-k故障的不确定集；建立考虑N-k故障的两阶段鲁棒应急调度模型，上层为考虑频率安全约束的预防性机组组合，下层模拟N-k故障后应急调度；采用列和约束生成算法进行高效求解。仿真实验表明：所提模型能有效协调系统运行经济性与频率安全，提升电网在复杂多重故障工况下的抗扰动能力。

关键词: 动态频率安全, 应急调度, 抽水蓄能, 二阶锥, N-k故障, 两阶段鲁棒

Abstract:

To address the risk of system inertia loss and frequency instability caused by grid integration of high-proportioned new energy and unit failures, an N-k robust emergency dispatch method considering dynamic frequency security constraints was proposed. With the consideration of the frequency response characteristics of variable-speed pumped storage, a dynamic frequency response model incorporating variable-speed pumped storage was constructed, and the nadir frequency constraint was established through second-order cone transformation. Information entropy theory was employed to quantify the uncertainty of unit failures, and an uncertainty set considering N-k unit failures was developed. A two-stage robust emergency dispatch model considering N-k failures was established. The upper layer involved preventive unit commitment considering frequency security constraints, and the lower layer simulated post-N-k failure emergency dispatch. The column-and-constraint generation algorithm was used for the efficient solution. The simulation experiments have demonstrated that the proposed model effectively balances system operational economy and frequency security, enhancing the grid's resilience under conditions with complex and multiple failures.

Key words: dynamic frequency security, emergency dispatch, pumped storage, second-order cone, N-k failure, two-stage robust

中图分类号:

TP391.9

黄涛,张智,丁玉杰等 . 考虑动态频率安全与N-k故障的鲁棒应急调度方法[J]. 系统仿真学报, 2025, 37(12): 2981-2993.

Huang Tao,Zhang Zhi,Ding Yujie,et al . Robust Emergency Dispatch Method Considering Dynamic Frequency Security and N-k Contingency[J]. Journal of System Simulation, 2025, 37(12): 2981-2993.

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参数	数值
定速抽蓄机组抽水功率/MW	150
定速抽蓄机组发电功率/MW	[75, 150]
变速抽蓄机组抽水/发电功率范围/MW	[110, 165]/[52.5, 150]
定/变速抽蓄发电运行效率/%	90
定速抽蓄抽水运行效率/%	80
抽蓄电站最大增开机/泵台数	2/2

场景	含变速抽蓄	考虑因素
场景	含变速抽蓄	故障熵约束	频率安全约束
Ⅰ	×	×	√
Ⅱ	√	×	√
Ⅲ	√	√	×
Ⅳ	√	√	√

场景	发电成本	开停机成本	备用成本	总成本
1	385 120.7	2 120	55 676.0	442 916.7
2	380 813.6	2 000	49 675.9	432 489.5
3	378 449.5	1 860	27 680.8	407 990.3
4	377 662.5	1 950	33 684.9	413 297.4