Microgrid system allocation using a bi-level intelligent approach and demand-side management

Demand-side management (DSM) segregates the elastic and inelastic loads and restructures the load demand model of a distribution system by minimizing the operational cost of the entire process. This is done by optimally transferring the flexible loads to hours when the per-unit cost of utility is lo...

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Bibliographic Details
Published in:MRS energy & sustainability 2023-03, Vol.10 (1), p.113-125
Main Authors: Dey, Bishwajit, Basak, Sourav, Bhattacharyya, Biplab
Format: Article
Language:English
Subjects:
Algorithms
Alternative energy sources
Chemistry and Materials Science
Costs
Demand side management
Distributed generation
Economics and Management
Electric power demand
Electrical loads
Energy management
Energy Materials
Energy Policy
Energy storage
Fossil fuels
Generators
Genetic algorithms
Lagrange multiplier
Linear programming
Load distribution
Materials Engineering
Materials Science
Operating costs
Optimization
Optimization algorithms
Optimization techniques
Original Research
Peak demand
Peak load
Production planning
Renewable and Green Energy
Renewable energy sources
Scheduling
Sustainable Development
Swarm intelligence
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Summary:Demand-side management (DSM) segregates the elastic and inelastic loads and restructures the load demand model of a distribution system by minimizing the operational cost of the entire process. This is done by optimally transferring the flexible loads to hours when the per-unit cost of utility is lower. This paper performs a bi-level optimization strategy to lower the operating expense of a low-voltage microgrid (LV MG) system operating in grid-connected mode, comprising battery energy storage (BES), renewable energy sources (RES), and fossil fuel-powered generators. In the first level of optimization, the load model is restructured as per the DSM participation level. Thereafter, the restructured load demand model is considered, and optimal allocation for distributed generators (DGs) is percolated for minimizing the generation cost of the microgrid system in the second level. A recently developed hybrid swarm intelligence algorithm that has already been used in solving diverse power system optimization problems was used as the optimization tool for the study. The generation cost was minimized for different grid participation types and grid pricing strategies with and without consideration of DSM. The numerical results show a 55–75% reduction in generation cost when 20–30% DSM participation was considered. Graphical abstract Highlights The generation cost of an LV microgrid (MG) system was evaluated for diverse grid-dependent scenarios. The impact of demand-side management on the performance of the MG system and generation costs was studied. Discussion The work described in this paper initially restructured the forecasted load demand for different DSM participation levels to reduce the peak demand and improve the load factor of the MG system. Thereafter, the generation costs were evaluated for diverse grid-dependent scenarios and compared for various load demand models obtained after DSM implementation.
ISSN:2329-2237
2329-2229
2329-2237
DOI:10.1557/s43581-022-00057-5