IoT-based optimal demand side management and control scheme for smart microgrid

[Display omitted] •Proposing an optimal EMS for grid-connected SMG.•The technique based on the ToU pricing principle and SMG appliances contr.•This is achieved by solving a two-level optimization problem.•Proposing a robust control scheme to enhance system dynamic response.•Applying IoT to communica...

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Bibliographic Details
Published in:International journal of electrical power & energy systems 2021-05, Vol.127, p.106674, Article 106674
Main Authors: Sedhom, Bishoy E., El-Saadawi, Magdi M., El Moursi, M.S., Hassan, Mohamed.A., Eladl, Abdelfattah A.
Format: Article
Language:English
Subjects:
Demand-side management
Energy management
IoT
Photovoltaic and storage system
Smart microgrid
Wind generator
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Summary:[Display omitted] •Proposing an optimal EMS for grid-connected SMG.•The technique based on the ToU pricing principle and SMG appliances contr.•This is achieved by solving a two-level optimization problem.•Proposing a robust control scheme to enhance system dynamic response.•Applying IoT to communicate between the appliances and management system.•A prototype is made to validate the proposed management-control strategy. Renewable energy resources (RESs) are highly speared to cover colossal electricity demand. Smart microgrids (SMGs) are engaged with demand-side management (DSM) to save more energy and maximize energy efficiency. Voltage and frequency regulations, CO2 emission, peak-to-average ratio (PAR), RES stochastic nature, and load dynamics are still considered the most SMG challenges. New control and management approaches are needed to overcome these challenges. Internet of Things (IoT) is accomplished to provide adaptive monitoring of energy consumption and ensure an economical and secure operation of the SMG. This paper proposes an advanced DSM and control strategy for an efficient energy management system (EMS) in SMG. An optimal cost-effective EMS operation is firstly introduced based on a two-level genetic algorithm (GA) optimization problem and augmented with the time-of-use pricing (ToU) principle. Secondly, the SMG voltage and frequency are optimally regulated using an improved PID-based mixed sensitivity H-infinity (PID-MSH∞) control scheme while operating in islanded mode. The proposed DSM and control strategy harness the immense IoT aptitudes to ensure an economic and secure operation of the SMG. Finally, a SMG lab-scale prototype is experimentally implemented to realize and validate the proposed DSM and control strategy. The experimental results prove the efficacy of the proposed EMS and the effectiveness of the SMG operation. The results confirm the proposed scheme's capability to get an optimal DSM scheme with reducing the SMG energy cost, emission cost, and PAR. The proposed control scheme accomplishes the SMG voltage and frequency regulations in adherence to IEEE Standard-1547 and provides customers' quality of service while customizing voltage for regulating DSM.
ISSN:0142-0615
1879-3517
DOI:10.1016/j.ijepes.2020.106674