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Enhancing Active Distribution Systems Resilience by Fully Distributed Self-Healing Strategy

Reza Roofegari Nejad, Wei Sun

2021IEEE Transactions on Smart Grid39 citationsDOIOpen Access PDF

Abstract

Distributed restoration can exploit smart grid technologies to enhance the resilience of active distribution networks toward a self-healing smart grid. However, the large number of decision variables, especially the binary ones for reconfiguration, bring challenges to developing scalable distributed distribution service restoration (DDSR) strategies. This paper proposes a fully distributed solution procedure based on the alternating direction method of multipliers (ADMM) for mixed-integer programming problems and applies to develop the DDSR framework. The method consists of relax-drive-polish phases, 1) relaxing binary variables, and applying the convex ADMM as a warm start; 2) driving the solutions toward Boolean values through a proximal operator; 3) fixing the obtained binding binary variables and solving the rest of the problem to polish results and achieve a high-quality suboptimal solution. Then, an autonomous clustering strategy and consensus ADMM are integrated with the proposed method to realize the fully distributed cluster-based framework of DDSR. This framework can first determine DER scheduling and switch status for reconfiguration to energize the out-of-service areas from local faults, and then provide the load restoration solution in a distributed manner for total blackouts in large-scale distribution networks. The effectiveness and scalability of the proposed DDSR framework are demonstrated through testing on the IEEE 123-node, IEEE 8500-node, and synthetic 100k-node test feeders.

Topics & Concepts

ScalabilityDistributed computingComputer scienceControl reconfigurationSmart gridScheduling (production processes)Cluster analysisDistributed algorithmGridMathematical optimizationEngineeringMathematicsEmbedded systemArtificial intelligenceGeometryDatabaseElectrical engineeringOptimal Power Flow DistributionMicrogrid Control and OptimizationSmart Grid Security and Resilience