Advanced energy management strategy for microgrid using real-time monitoring interface

Recently, the integration of renewable energy sources in microgrids has seen a significant rise due to their attractive prices, reliability etc. However, besides the techno-economic benefits, the renewable energy sources are intermittent, and the high penetration of renewable sources into the microg...

Full description

Saved in:
Bibliographic Details
Published in:Journal of energy storage 2022-08, Vol.52, p.104814, Article 104814
Main Authors: Ullah, Zia, Wang, Shoarong, Wu, Guoan, Xiao, Mengmeng, Lai, Jinmu, Elkadeem, Mohamed R.
Format: Article
Language:English
Subjects:
Energy management
Microgrid
Microgrid monitoring
Renewable energy
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Recently, the integration of renewable energy sources in microgrids has seen a significant rise due to their attractive prices, reliability etc. However, besides the techno-economic benefits, the renewable energy sources are intermittent, and the high penetration of renewable sources into the microgrid poses design and operation challenges. Indeed, an efficient energy management strategy (EMS) is required to govern power flows across the entire microgrid. This paper introduces an advanced EMS design with a real-time monitoring interface for the effective operation of the hybrid microgrid and data analysis. The proposed advanced EMS model uses a real-time monitoring interface, and it provides the optimum operation and control in terms of balanced power supply and voltage profile with stable frequency. We designed the microgrid, which comprises hybrid sources such as solar and wind power sources, Li-ion battery storage system, backup electrical grids, and AC/DC loads, considering the functional constraints of a microgrid energy management and stability. In addition, the battery energy storage is effectively managed through the performance control of battery charging and discharging using an efficiency controller. The proposed system control is based on the optimum power supply of loads through the available renewable sources and the battery State of Charge (SOC). The microgrid measurement data is transmitted through the Python platform and a graphical user interface (GUI) software developed for data analysis. The simulation results using Matlab Simulink and Python platforms demonstrate the relevance and effectiveness of the proposed EMS and monitoring interface for the stable and reliable operation of the developed hybrid microgrid. •This paper proposes an advanced energy management strategy (EMS) for the hybrid microgrid encompassing renewable sources, storage, backup electrical grids, and AC/DC loads.•An advanced EMS model design is implemented in Matlab Simulink for the hybrid microgrid.•A real-time monitoring interface in the Python platform has been implemented for hybrid microgrid energy management and data analysis.•An efficiency controller is implemented for optimal control of battery operation.•The proposed model provides a balanced power supply, stable voltage profile and frequency during various meteorological conditions and loads variations.
ISSN:2352-152X
2352-1538
DOI:10.1016/j.est.2022.104814