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A Three-Phase Weather-Dependent Power Flow Approach for 4-Wire Multi-Grounded Unbalanced Microgrids With Bare Overhead Conductors

Evangelos Pompodakis, Arif Ahmed, Minas C. Alexiadis

2020IEEE Transactions on Power Systems31 citationsDOI

Abstract

Conventional power flow algorithms assume that the network resistances and reactances remain constant regardless of the weather and loading conditions. Although the impact of the weather in power flow analysis has been recently investigated via weather-dependent power flow (WDPF) approaches, the magnetic effects in the core of Aluminum Conductor Steel Reinforced (ACSR) conductors have not been explicitly considered. ACSR conductors are widely used in distribution networks. Therefore, this manuscript proposes a three-phase weather-dependent power flow algorithm for 4-wire multi-grounded unbalanced microgrids (MGs), which takes into consideration the impact of weather as well as the magnetic effects in the core of ACSR conductors. It is shown that the magnetic effects in the core can significantly influence the power flow results, especially for networks composed of single-layer ACSR conductors. Furthermore, the proposed algorithm explicitly considers the multi-grounded neutral conductor, thus it can precisely simulate unbalanced low voltage (LV) and medium voltage (MV) networks. In addition, the proposed approach is generic and can be applied in both grid-connected and islanded networks. Simulations conducted in a 25-Bus unbalanced LV microgrid (MG) highlight the accuracy and benefit of the proposed approach, while its computation performance is tested in the IEEE 8500-Node network.

Topics & Concepts

Electrical conductorConductorOverhead (engineering)MicrogridVoltageGridNode (physics)Computer sciencePower (physics)Electrical engineeringEngineeringMaterials scienceStructural engineeringPhysicsMathematicsComposite materialQuantum mechanicsGeometryThermal Analysis in Power TransmissionOptimal Power Flow DistributionHVDC Systems and Fault Protection