MPC-based double-layer real-time conditional cSelf-restoration for interconnected microgrids

Abstract In this work, we propose a novel model predictive control(MPC)-based real-time conditional self-restoration energy management system (CSR-EMS) for interconnected microgrids (IMGs) integrated with renewable energy sources (RESs) and energy storage systems (ESSs). Superior to the existing IMG self-restoration methods, the “conditionality” of the proposed CSR-EMS can economically realize self-restoration and grid-assisted restoration during energy deficiency or faults, in both islanded and grid-connected modes. Cost minimization is implemented as the objective function to judge in real-time which restoration mode is economically preferred. The proposed CSR-EMS comprises two layers–the lower layer operates locally to eliminate electricity fluctuations created by RESs and ensure economic effectiveness within an MG, whereas the upper layer oversees the real-time operational status of the IMG system and determines power exchange among microgrids (MGs) during abnormalities. In detail, when a microgrid inside the IMG system experiences an energy deficiency, the CSR-EMS, on an MPC basis, intelligently optimizes power production from each dispatchable distributed generator (DG), ESS, power imported from the main grid, and power exchange among the IMGs to maintain the demand–supply balance, while considering system recovery cost, state of charge (SoC) of ESSs and operation modes of the IMGs (i.e., grid-connected or islanded mode). Simulation results and comparisons with existing IMG self-healing EMSs demonstrate the economic efficacy of the proposed CSR-EMS strategy during normal and abnormal operations, which can be used as an energy control framework for modern power systems with multiple interconnected microgrids.

[1]  Antonio Vicino,et al.  Bidding Wind Energy Exploiting Wind Speed Forecasts , 2016, IEEE Transactions on Power Systems.

[2]  Arindam Ghosh,et al.  Networked Microgrids: State-of-the-Art and Future Perspectives , 2019, IEEE Transactions on Industrial Informatics.

[3]  Chandra Prakash Gupta,et al.  Priority-Based Scheduling of Energy Exchanges Between Cooperative Microgrids in Risk-Averse Environment , 2020, IEEE Systems Journal.

[4]  Jianxue Wang,et al.  A Risk-Averse Conic Model for Networked Microgrids Planning With Reconfiguration and Reorganizations , 2020, IEEE Transactions on Smart Grid.

[5]  Ahmed Ouammi,et al.  Supervisory Model Predictive Control for Optimal Energy Management of Networked Smart Greenhouses Integrated Microgrid , 2020, IEEE Transactions on Automation Science and Engineering.

[6]  Samson Shenglong Yu,et al.  An Enhanced Adaptive Phasor Power Oscillation Damping Approach With Latency Compensation for Modern Power Systems , 2018, IEEE Transactions on Power Systems.

[7]  Hong-Hee Lee,et al.  A Novel Dual-Battery Energy Storage System for Wind Power Applications , 2016, IEEE Transactions on Industrial Electronics.

[8]  Hossein Seifi,et al.  Electric Power System Planning: Issues, Algorithms and Solutions , 2011 .

[9]  Samson Shenglong Yu,et al.  Demand-Side Regulation Provision From Industrial Loads Integrated With Solar PV Panels and Energy Storage System for Ancillary Services , 2018, IEEE Transactions on Industrial Informatics.

[10]  Mohammad Shahidehpour,et al.  Multiperiod Distribution System Restoration With Routing Repair Crews, Mobile Electric Vehicles, and Soft-Open-Point Networked Microgrids , 2020, IEEE Transactions on Smart Grid.

[11]  Jianhui Wang,et al.  Networked Microgrids for Self-Healing Power Systems , 2016, IEEE Transactions on Smart Grid.

[12]  Kai Strunz,et al.  Cooperative MPC-Based Energy Management for Networked Microgrids , 2017, IEEE Transactions on Smart Grid.

[13]  Josep M. Guerrero,et al.  A Two-Layer Distributed Cooperative Control Method for Islanded Networked Microgrid Systems , 2020, IEEE Transactions on Smart Grid.

[14]  Abdullah Abusorrah,et al.  Flexible Division and Unification Control Strategies for Resilience Enhancement in Networked Microgrids , 2020, IEEE Transactions on Power Systems.

[15]  Nicholas A. DiOrio,et al.  Economic Analysis Case Studies of Battery Energy Storage with SAM , 2015 .

[16]  Yusef Esa,et al.  Applications of Complex Network Analysis in Electric Power Systems , 2018, Energies.

[17]  Wei Sun,et al.  Optimal self‐healing strategy for microgrid islanding , 2018, IET Smart Grid.

[18]  Tyrone Fernando,et al.  A complex network theory analytical approach to power system cascading failure-From a cyber-physical perspective. , 2019, Chaos.

[19]  Alberto Berrueta,et al.  Combined dynamic programming and region-elimination technique algorithm for optimal sizing and management of lithium-ion batteries for photovoltaic plants , 2018, Applied Energy.

[20]  Ashok M. Jadhav,et al.  Priority-Based Energy Scheduling in a Smart Distributed Network With Multiple Microgrids , 2017, IEEE Transactions on Industrial Informatics.

[21]  Almoataz Y. Abdelaziz,et al.  A Planning Framework for Optimal Partitioning of Distribution Networks Into Microgrids , 2020, IEEE Systems Journal.

[22]  Lingfeng Wang,et al.  A Transactive Energy Framework for Coordinated Energy Management of Networked Microgrids With Distributionally Robust Optimization , 2020, IEEE Transactions on Power Systems.