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Coordination of preventive, emergency and restoration dispatch against cascading failures for resilience enhancement

Siqi Huang, Changcheng Li

2024International Journal of Electrical Power & Energy Systems12 citationsDOIOpen Access PDF

Abstract

• The problem of potential changes in propagation paths generated by different prevention strategies is addressed. • A multi-stage coordination model is proposed for reducing cascading failure impacts. • A double-layer optimization framework is proposed for solving the multi-stage coordination dispatch model. Blackout events caused by cascading failures have induced enormous losses in power systems. Good defense strategies are helpful for stopping cascading failures spread, which not only reduces system losses, but also improves the system’s ability to cope with the cascading failures. However, the current studies mostly focus on single-stage defense strategy and lack coordination of preventive, emergency and restoration dispatch (CPERD) against cascading failures. This paper proposes a CPERD methodology to counteract cascading failures for resilience enhancement. We first analyze the propagation mechanism and the prediction method for the propagation paths of cascading failures. Second, we explore the necessity and feasibility of whole-process coordinated dispatch under cascading failures and design a CPERD model framework. Based on this framework, we further analyze the impact of whole-process coordinated dispatch on the propagation path of cascading failures. Third, preventive dispatch, emergency dispatch and restoration dispatch sub-models are separately modeled to minimize the dispatch cost. Since the model has the characteristics of multi-stage and multi-objective, a double-layer optimization framework and an improved particle swarm optimization algorithm are introduced to solve the CPERD problem. Finally, the IEEE 39-bus and IEEE 118-bus test systems are taken as examples for simulation analysis. The results show that whole-process coordinated dispatch can effectively reduce the final load loss and overall dispatch cost, and enhance power system resilience against cascading failures.

Topics & Concepts

Resilience (materials science)Cascading failureElectric power systemComputer scienceReliability engineeringRisk analysis (engineering)EngineeringBusinessPower (physics)Materials sciencePhysicsQuantum mechanicsComposite materialInfrastructure Resilience and Vulnerability AnalysisSmart Grid Security and ResiliencePower System Reliability and Maintenance