Multi-Objective Optimal Scheduling of a Microgrid Using Oppositional Gradient-Based Grey Wolf Optimizer

Multi-Objective Optimal Scheduling of a Microgrid Using Oppositional Gradient-Based Grey Wolf Optimizer

Optimal energy management has become a challenging task to accomplish in today’s advanced energy systems. If energy is managed in the most optimal manner, tremendous societal benefits can be achieved such as improved economy and less environmental pollution. It is possible to operate the microgrids...

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Bibliographic Details
Published in:Energies (Basel) Vol. 15; no. 23; p. 9024
Main Authors: Rajagopalan, Arul, Nagarajan, Karthik, Montoya, Oscar Danilo, Dhanasekaran, Seshathiri, Kareem, Inayathullah Abdul, Perumal, Angalaeswari Sendraya, Lakshmaiya, Natrayan, Paramasivam, Prabhu
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-12-2022
MDPI
Subjects:
Air pollution
Algorithms
Alternative energy sources
Distributed generation
Emission analysis
Energy
Energy management
Energy management systems
Energy resources
Energy sources
Energy storage
Fuel cells
Fuel technology
Generators
gradient-based grey wolf optimizer
Industrial plant emissions
Linear programming
Mathematical optimization
Methods
microgrid
Mitigation
multi-objective optimization
Operating costs
optimal scheduling
Optimization
Optimization algorithms
Optimization techniques
Pollutants
Pollution
Pollution control
renewable energy
Renewable energy sources
Renewable resources
Researchers
Scheduling (Management)
Test systems
Turbines
Wind power
India
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Summary:Optimal energy management has become a challenging task to accomplish in today’s advanced energy systems. If energy is managed in the most optimal manner, tremendous societal benefits can be achieved such as improved economy and less environmental pollution. It is possible to operate the microgrids under grid-connected, as well as isolated modes. The authors presented a new optimization algorithm, i.e., Oppositional Gradient-based Grey Wolf Optimizer (OGGWO) in the current study to elucidate the optimal operation in microgrids that is loaded with sustainable, as well as unsustainable energy sources. With the integration of non-Renewable Energy Sources (RES) with microgrids, environmental pollution is reduced. The current study proposes this hybrid algorithm to avoid stagnation and achieve premature convergence. Having been strategized as a bi-objective optimization problem, the ultimate aim of this model’s optimal operation is to cut the costs incurred upon operations and reduce the emission of pollutants in a 24-h scheduling period. In the current study, the authors considered a Micro Turbine (MT) followed by a Wind Turbine (WT), a battery unit and a Fuel Cell (FC) as storage devices. The microgrid was assumed under the grid-connected mode. The authors validated the proposed algorithm upon three different scenarios to establish the former’s efficiency and efficacy. In addition to these, the optimization results attained from the proposed technique were also compared with that of the results from techniques implemented earlier. According to the outcomes, it can be inferred that the presented OGGWO approach outperformed other methods in terms of cost mitigation and pollution reduction.
Bibliography:Energies
ISSN:1996-1073
1996-1073
DOI:10.3390/en15239024