Hierarchical Two-Layer Distributed Control Architecture for Voltage Regulation in Multiple Microgrids in the Presence of Time-Varying Delays

The Multiple Microgrids (MMGs) concept has been identified as a promising solution for the management of large-scale power grids in order to maximize the use of widespread renewable energies sources. However, its deployment in realistic operation scenarios is still an open issue due to the presence of non-ideal and unreliable communication systems that allow each component within the power network to share information about its state. Indeed, due to technological constraints, multiple time-varying communication delays consistently appear during data acquisition and the transmission process and their effects must be considered in the control design phase. To this aim, this paper addresses the voltage regulation control problem for MMGs systems in the presence of time-varying communication delays. To solve this problem, we propose a novel hierarchical two-layer distributed control architecture that accounts for the presence of communication latencies in the information exchange. More specifically, the upper control layer aims at guaranteeing a proper and economical reactive power dispatch among MMGs, while the lower control layer aims at ensuring voltage regulation of all electrical buses within each MG to the desired voltage set-point. By leveraging a proper Driver Generator Nodes Selection Algorithm, we first provide the best choice of generator nodes which, considering the upper layer control goal, speeds up the voltage synchronization process of all the buses within each MG to the voltage set-point computed by the upper-control layer. Then, the lower control layer, on the basis of this desired voltage value, drives the reactive power capability of each smart device within each MG and compensates for possible voltage deviations. Simulation analysis is carried out on the realistic case study of an MMGs system consisting of two identical IEEE 14-bus test systems and the numerical results disclose the effectiveness of the proposed control strategy, as well as its robustness with respect to load fluctuations.

[1]  Xinghuo Yu,et al.  Optimal pinning controllability of complex networks: dependence on network structure. , 2015, Physical review. E, Statistical, nonlinear, and soft matter physics.

[2]  Xinghuo Yu,et al.  Cluster-Oriented Distributed Cooperative Control for Multiple AC Microgrids , 2019, IEEE Transactions on Industrial Informatics.

[3]  Behnam Mohammadi-Ivatloo,et al.  Flexible scheduling of reconfigurable microgrid-based distribution networks considering demand response program , 2020 .

[4]  Mohammad Shahidehpour,et al.  Microgrid Topology Planning for Enhancing the Reliability of Active Distribution Networks , 2018, IEEE Transactions on Smart Grid.

[5]  Giovanni Fiengo,et al.  Distributed leader-tracking adaptive control for high-order nonlinear Lipschitz multi-agent systems with multiple time-varying communication delays , 2019, Int. J. Control.

[6]  Alfredo Vaccaro,et al.  Decentralized Smart Grid Voltage Control by Synchronization of Linear Multiagent Systems in the Presence of Time-Varying Latencies , 2019 .

[7]  Carlos Moreira,et al.  Control strategies for Multi-Microgrids islanding operation through Smart Transformers , 2019, Electric Power Systems Research.

[8]  Giovanni Fiengo,et al.  Distributed robust output consensus for linear multi‐agent systems with input time‐varying delays and parameter uncertainties , 2019, IET Control Theory & Applications.

[9]  Gang Feng,et al.  Robust cooperative output regulation of multi-agent systems via adaptive event-triggered control , 2019, Autom..

[10]  Bishoy E. Sedhom,et al.  IET Renewable Power Generation Special Issue: Challenges in Future Grid-Interactive Power Converters: Control Strategies, Optimal Operation, and Corrective Actions H-Infinity versus model predictive control methods for seamless transition between islanded- and grid-connected modes of microgrids , 2020 .

[11]  Josep M. Guerrero,et al.  Distributed Secondary Voltage and Frequency Control for Islanded Microgrids With Uncertain Communication Links , 2017, IEEE Transactions on Industrial Informatics.

[12]  Antonio Saverio Valente,et al.  Adaptive synchronization of linear multi-agent systems with time-varying multiple delays , 2017, J. Frankl. Inst..

[13]  Lu Qu,et al.  Active Output-Voltage-Sharing Control Scheme for Input Series Output Series Connected DC–DC Converters Based on a Master Slave Structure , 2017, IEEE Transactions on Power Electronics.

[14]  Xinghuo Yu,et al.  Survey on Recent Advances in Networked Control Systems , 2016, IEEE Transactions on Industrial Informatics.

[15]  Abdullah Abusorrah,et al.  Optimal Interconnection Planning of Community Microgrids With Renewable Energy Sources , 2017, IEEE Transactions on Smart Grid.

[16]  Vishal Kumar,et al.  Microgrid control: A comprehensive survey , 2018, Annu. Rev. Control..

[17]  Xiaoqing Lu,et al.  A Novel Secondary Power Management Strategy for Multiple AC Microgrids With Cluster-Oriented Two-Layer Cooperative Framework , 2021, IEEE Transactions on Industrial Informatics.

[18]  Bo Zhao,et al.  Energy Management of Multiple Microgrids Based on a System of Systems Architecture , 2018, IEEE Transactions on Power Systems.

[19]  Lu Ziguang,et al.  Distributed secondary control based on cluster consensus of inhibitory coupling with power limit for isolated multi-microgrid , 2019 .

[20]  Alfredo Vaccaro,et al.  A Decentralized Architecture Based on Cooperative Dynamic Agents for Online Voltage Regulation in Smart Grids , 2019, Energies.

[21]  Osama A. Mohammed,et al.  Multiagent-Based Optimal Microgrid Control Using Fully Distributed Diffusion Strategy , 2017, IEEE Transactions on Smart Grid.

[22]  Josep M. Guerrero,et al.  MAS-Based Distributed Coordinated Control and Optimization in Microgrid and Microgrid Clusters: A Comprehensive Overview , 2018, IEEE Transactions on Power Electronics.

[23]  P.H.A. Barra,et al.  A survey on adaptive protection of microgrids and distribution systems with distributed generators , 2020 .

[24]  Islam Safak Bayram,et al.  Planning, operation, and protection of microgrids : an overview , 2017 .

[25]  Christoforos N. Hadjicostis,et al.  A Two-Stage Distributed Architecture for Voltage Control in Power Distribution Systems , 2013, IEEE Transactions on Power Systems.

[26]  Stefania Santini,et al.  A Secure Adaptive Control for Cooperative Driving of Autonomous Connected Vehicles in the Presence of Heterogeneous Communication Delays and Cyberattacks , 2020, IEEE Transactions on Cybernetics.

[27]  Subrata K. Sarker,et al.  A survey on control issues in renewable energy integration and microgrid , 2019, Protection and Control of Modern Power Systems.

[28]  Xinghuo Yu,et al.  Finding the Most Influential Nodes in Pinning Controllability of Complex Networks , 2017, IEEE Transactions on Circuits and Systems II: Express Briefs.

[29]  Jin Jiang,et al.  Accurate Reactive Power Sharing in an Islanded Microgrid Using Adaptive Virtual Impedances , 2015, IEEE Transactions on Power Electronics.

[30]  T. Carroll,et al.  Master Stability Functions for Synchronized Coupled Systems , 1998 .

[31]  H. T. Mouftah,et al.  Reliable overlay topology design for the smart microgrid network , 2011, IEEE Network.

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

[33]  Josep M. Guerrero,et al.  Distributed Coordination of Islanded Microgrid Clusters Using a Two-Layer Intermittent Communication Network , 2018, IEEE Transactions on Industrial Informatics.

[34]  Chengxiao Zhang,et al.  Sampling-based self-triggered coordination control for multi-agent systems with application to distributed generators , 2018, Int. J. Syst. Sci..

[35]  Yu Wang,et al.  Peer-to-Peer Control for Networked Microgrids: Multi-Layer and Multi-Agent Architecture Design , 2020, IEEE Transactions on Smart Grid.