An Optimal Energy Management System for Real-Time Operation of Multiagent-Based Microgrids Using a T-Cell Algorithm

Harmouch, Fatima Zahra; Ebrahim, Ahmed F.; Esfahani, Mohammad Mahmoudian; Krami, Nissrine; Hmina, Nabil; Mohammed, Osama A.

doi:10.3390/en12153004

Cited by 9 publications

(3 citation statements)

References 41 publications

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“…In this work, the proposed system takes into consideration the two modes in parallel; real-time and day-ahead scheduling. The estimated response time of the real-time scheduling system, proposed in this work, does not exceed 2 minutes, which falls within the definition of real time [38]. This time includes the acquisition and control time and the optimization and classification time.…”

Section: Simulation Resultsmentioning

confidence: 73%

An intelligent energy management system for optimum design and real-time operation

Zedak¹,

Belfqih²,

Boukherouaa³

et al. 2023

IJPEDS

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<span lang="EN-US">Planning and management of distribution networks has become a very difficult task, especially with the strong expansion of renewable energy sources (RES) which are intermittent in nature. Maintaining fluidity and reliability of real-time decisions while taking into consideration uncertainties related to production and increasing the profit of distribution network operators is the objective of the system proposed in this work. It is an intelligent energy management system dedicated to the management of grid-integrated RES and battery energy storage systems (BESS), composed of: i) a real-time control and data acquisition model, ii) a model for forecasting the intermittent parameters of RES based on neural networks, iii) a long-term planning model based on the optimal placement and size of RES and BESS, and iv) an hourly planning model for scheduling the energy distribution between energy sources. The non-dominated sorting genetic algorithm and the entropy-TOPSIS method (technique for order of preference by similarity to ideal solution) form the basic block of this model. To evaluate it, a modified IEEE 33 bus network was used for testing and the results, for short-term scheduling, proved that the system succeeds in maximizing profits and significantly minimizing CO<sub>2</sub> emissions, in addition to power losses and voltage drops.</span>

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Section: Simulation Resultsmentioning

confidence: 73%

An intelligent energy management system for optimum design and real-time operation

Zedak¹,

Belfqih²,

Boukherouaa³

et al. 2023

IJPEDS

View full text Add to dashboard Cite

show abstract

“…(Anvari-Moghaddam et al , 2017) proposed a practical framework of an ontology-driven MAS based energy management system (EMS) for monitoring and optimal control of buildings and micro-grid systems. In the same theme, the works presented in (Kofinas et al , 2018) and (Harmouch et al , 2019) discussed a real-time operation of the energy management system, which is based on MAS and fast converging T-Cell algorithm. These works aim to decrease the grid working cost and maximize the real-time response in the network.…”

Section: Related Workmentioning

confidence: 99%

An intelligent system for energy management in smart cities based on big data and ontology

Sayah

Kazar

Lejdel³

et al. 2020

SASBE

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PurposeThis research paper aims at proposing a framework based on semantic integration in Big Data for saving energy in smart cities. The presented approach highlights the potential opportunities offered by Big Data and ontologies to reduce energy consumption in smart cities.Design/methodology/approachThis study provides an overview of semantics in Big Data and reviews various works that investigate energy saving in smart homes and cities. To reach this end, we propose an efficient architecture based on the cooperation between ontology, Big Data, and Multi-Agent Systems. Furthermore, the proposed approach shows the strength of these technologies to reduce energy consumption in smart cities.FindingsThrough this research, we seek to clarify and explain both the role of Multi-Agent System and ontology paradigms to improve systems interoperability. Indeed, it is useful to develop the proposed architecture based on Big Data. This study highlights the opportunities offered when they are combined together to provide a reliable system for saving energy in smart cities.Practical implicationsThe significant advancement of contemporary applications (smart cities, social networks, health care, IoT, etc.) requires a vast emergence of Big Data and semantics technologies in these fields. The obtained results provide an improved vision of energy-saving and environmental protection while keeping the inhabitants’ comfort.Originality/valueThis work is an efficient contribution that provides more comprehensive solutions to ontology integration in the Big Data environment. We have used all available data to reduce energy consumption, promote the change of inhabitant’s behavior, offer the required comfort, and implement an effective long-term energy policy in a smart and sustainable environment.

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“…In terms of energy management algorithm verification, reference [16] proposed a layered energy management strategy, verified its own algorithm using a laboratory-level experimental platform, and performed a simplified simulation at a given time scale. Reference [17] used a layered multi-agent EMS structure and proposed solutions for improving the calculation speed of energy management. It also utilized a laboratory-level experimental platform to verify its own algorithm.…”

Section: Introductionmentioning

confidence: 99%

Research on Multi-Scenario Variable Parameter Energy Management Strategy of Rural Community Microgrid

et al. 2020

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Many rural communities in western China use renewable energy-based clean energy supply methods, and the community microgrid system of “photovoltaic + energy storage + electric heating” has been widely used. However, the energy management effect of such a typical rural community microgrid system is not very satisfactory. Aiming at the problem of the comprehensive economic operation of the microgrid system in rural communities, a method for optimizing the operation strategy parameters of typical operating scenarios is proposed, and critical parameters of the real-time energy management strategy of the microgrid system are optimized. Through the evaluation of the annual time-scale simulation results, it is proved that the proposed strategy can improve the comprehensive economic benefits of the operation of the rural community microgrid system (comprehensive economic benefits include electricity bills and energy storage system (ESS) life loss). Relying on the actual community microgrid demonstration project system in western China, a community-level microgrid energy management monitoring system is built. The control strategy proposed in this paper is applied to the demonstration system for experimental verification. The operational data of the demonstration system shows that the proposed method is feasible and effective.

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An Optimal Energy Management System for Real-Time Operation of Multiagent-Based Microgrids Using a T-Cell Algorithm

Cited by 9 publications

References 41 publications

An intelligent energy management system for optimum design and real-time operation

An intelligent energy management system for optimum design and real-time operation

An intelligent system for energy management in smart cities based on big data and ontology

Research on Multi-Scenario Variable Parameter Energy Management Strategy of Rural Community Microgrid

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