Operating Renewable Energy Communities to Reduce Power Peaks in the Distribution Grid: An Analysis on Grid-Friendliness, Different Shares of Participants, and Economic Benefits

Improving the control of flexible assets in distribution grids, e.g., battery storages, electric vehicle charging points, and heat pumps, can balance power peaks caused by high renewable power generation or load to prevent overloading the grid infrastructure. Renewable energy communities, introduced...

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Bibliographic Details
Published inEnergies (Basel) Vol. 15; no. 15; p. 5468
Main Authors Sudhoff, Robin, Schreck, Sebastian, Thiem, Sebastian, Niessen, Stefan
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.08.2022
Subjects
Alternative energy sources
distribution system operator
Electric power distribution
Electric vehicles
Electrical transmission
Electricity
Energy
energy communities
Energy management
Energy storage
Flexibility
grid-friendliness
Heat exchangers
Heat pumps
Linear programming
Load
Load distribution
Optimization
Peak load
Power management
prosumers
renewable energy communities
Renewable resources
Simulation
Substations
Systems stability
Topology
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Summary:Improving the control of flexible assets in distribution grids, e.g., battery storages, electric vehicle charging points, and heat pumps, can balance power peaks caused by high renewable power generation or load to prevent overloading the grid infrastructure. Renewable energy communities, introduced as part of the recast of the Renewable Energy Directive, provide a regulatory framework for this. As a multi-site energy management method, they can tap flexibility potential. The present work quantifies stimulus for renewable energy communities to incentivize the grid-friendly operation of flexible assets, depending on the shares of participants in rural, suburban, and urban grid topologies. Results indicate that an operation of the community, driven by maximizing the economic benefits of its members, does not clearly reduce the annual peak load at the low-voltage substation, while the operation strategy of a grid-friendly renewable energy community achieves a peak power reduction of 23–55%. When there is not full participation, forecasts of the residual load of non-participants provided by the distribution system operator can be considered in the optimization of the renewable energy community. For all simulation cases, the economic benefit between the two operation strategies differs by less than one percent, resulting in a very low additional incentive required for grid-friendliness in terms of reduced peak power. Thus, grid-friendly renewable energy communities might be a cost-effective way to defer future grid reinforcements.
ISSN:1996-1073
1996-1073
DOI:10.3390/en15155468