Litcius/Paper detail

A Reliability-Constrained Expansion Planning Model for Mesh Distribution Networks

Zihao Li, Wenchuan Wu, Xue‐Cheng Tai, Boming Zhang

2020IEEE Transactions on Power Systems91 citationsDOI

Abstract

To achieve high reliability, the urban distribution networks are mesh-constructed and radial-operated, in which the outage load can be restored to adjacent feeders via tie-lines after faults. Conventionally, iterative optimization-simulation methods and heuristics are adopted for distribution network planning, which cannot guarantee global optimality. Besides, existing reliability-constrained planning model cannot explicitly assess the reliability indices for mesh distribution networks, so the resulted plan scheme may be overly invested. In this paper, we propose a novel multistage expansion planning model for mesh distribution networks, in which reliability assessment is explicitly implemented as constraints. The different investment/reliability preferences for buses are also customized. Specifically, post-fault load restoration between feeders through tie-lines is modeled as a case of post-fault network reconfiguration. The planning model is then cast as an instance of mixed-integer linear programming and can be effectively solved by off-the-shelf solvers. We use a 54-node system to test the performance of proposed model. Simulation results show the effectiveness and flexibility of this methodology.

Topics & Concepts

Reliability (semiconductor)HeuristicsMathematical optimizationComputer scienceFlexibility (engineering)Control reconfigurationLinear programmingNode (physics)HeuristicReliability engineeringFault (geology)Integer programmingEngineeringPower (physics)MathematicsEmbedded systemGeologyStatisticsStructural engineeringSeismologyPhysicsQuantum mechanicsOptimal Power Flow DistributionPower System Reliability and MaintenanceAdvanced Optical Network Technologies