故障修复和拓扑重构协同的配电网灾后恢复调度

doi:10.3969/j.issn.2097-0706.2026.02.009

摘要/Abstract

摘要：

极端灾害事件容易导致配电网故障，影响供电可靠性。为提升配电网弹性恢复能力，建立了一种修复路径规划和拓扑重构协同的配电网灾后恢复模型。为制定有序故障修复计划，建立维修队路径规划的空间与时序约束，及其与拓扑重构耦合的故障状态约束；通过修复路径和拓扑重构协同优化，减少系统弃负荷；利用基于概率密度的模糊集描述新能源分布不确定性，利用分布鲁棒优化平衡调度决策鲁棒性与经济性；为高效求解所提模型，基于对偶理论处理概率密度不确定性，进一步移除约束中的min算子，从而将两阶段灾后恢复模型转化成非迭代的单阶段问题。算例测试表明，所提协同模型能够减少负荷损失，同时，所提分布鲁棒优化方法能够保证调度决策鲁棒性，并且能够在严格保证优化质量的基础上大幅提高计算效率。

关键词: 修复路径规划, 拓扑重构, 配电网弹性, 新能源, 分布鲁棒优化

Abstract:

Extreme disaster events frequently lead to distribution network faults，compromising power supply reliability. To enhance distribution network resilience，a post-disaster restoration model coordinating repair crew routing and network reconfiguration was established. To formulate an orderly fault repair plan，spatial and temporal constraints for repair crew routing were established，together with fault status constraints coupled with network reconfiguration. System load shedding was minimized through the coordinated optimization of repair paths and network reconfiguration. By leveraging probability density-based fuzzy sets to characterize the distribution uncertainty of renewable energy，distributionally robust optimization was employed to balance the robustness and economy of dispatch decisions. To efficiently solve the proposed model，probability density uncertainty was addressed based on duality theory，and the min operator within constraints was removed，whereby the two-stage post-disaster restoration model was converted into a non-iterative single-stage problem. Case studies demonstrated that the proposed coordinated model effectively reduced load losses. Furthermore，the proposed distributionally robust optimization method ensured the robustness of dispatch decisions and significantly enhanced computational efficiency while strictly maintaining optimization quality.

Key words: repair crew routing, network reconfiguration, distribution network resilience, renewable energy, distributionally robust optimization

中图分类号:

TK01：TM73

郑杨, 石龙, 陆烨, 郝广东. 故障修复和拓扑重构协同的配电网灾后恢复调度[J]. 综合智慧能源, 2026, 48(2): 96-105.

ZHENG Yang, SHI Long, LU Ye, HAO Guangdong. Post-disaster restoration scheduling of distribution networks coordinating fault repair and topology reconfiguration[J]. Integrated Intelligent Energy, 2026, 48(2): 96-105.

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故障线路	维修时间
故障线路	维修队1	维修队2
2—3	2	2
5— 6	2	3
8— 9	3	4
14—15	3	4
30 —31	2	2

策略	维修队	修复路径
1	1	线路2—3，8— 9，14—15
1	2	线路5—6，30—31
2	1	线路5—6，14—15，8— 9
2	2	线路30—31，2—3
3	1	线路2—3，14—15，5— 6
3	2	线路30 —31，8—9

策略	弃负荷/(MW∙h)	成本/万元
1	3.603 9	5.035 8
2	6.358 3	7.644 8
3	3.398 8	4.843 0

模型	弃负荷/(MW∙h)	成本/万元
确定性	3.462 1	4.907 4
分布鲁棒	3.398 8	4.843 0

方法	优化结果		样本外测试结果
方法	运行成本目标值/万元	耗时/s	运行成本经验期望值/万元	运行成本极端期望值/万元
随机	4.839 1	101	4.843 7	5.025 5
鲁棒	5.894 6	131	5.237 0	5.321 7
分布鲁棒	5.025 5	136	4.843 0	5.0255