Investigating the Impact of E-Mobility on Distribution Grids in Rural Communities: A Case Study

Marcus Brennenstuhl, Pawan Kumar Elangovan, Dirk Pietruschka () and Robert Otto
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Marcus Brennenstuhl: enisyst GmbH, Robert-Bosch-Straße 8/1, 72124 Pliezhausen, Germany
Pawan Kumar Elangovan: enisyst GmbH, Robert-Bosch-Straße 8/1, 72124 Pliezhausen, Germany
Dirk Pietruschka: Aschaffenburg UAS, Würzburger Str. 45, 63743 Aschaffenburg , Germany
Robert Otto: Center for Sustainable Energy Technology, University of Applied Sciences Stuttgart, Schellingstraße 24, 70174 Stuttgart, Germany

Energies, 2025, vol. 18, issue 21, 1-19

Abstract: Germany’s energy transition to a higher share of renewable energy sources (RESs) is characterized by decentralization, with citizens, cooperatives, SMEs, and municipalities playing a central role. As of early 2025, private individuals own a significant share of renewable energy installations, particularly PV panels, which corresponds to approximately half of the total installed PV power. This trend is driven by physical, technological, and societal factors. Technological advances in battery storage and sector coupling are expected to further decentralize the energy system. Thereby, the electrification of mobility, particularly through electric vehicles (EVs), offers significant storage potential and grid-balancing capabilities via bidirectional charging, although it also introduces challenges, especially for distribution grids during peak loads. Within this work we present a detailed digital twin of the entire distribution grid of the rural German municipality of Wüstenrot. Using grid operator data and transformer measurements, we evaluate strategic expansion scenarios for electromobility, PV and heat pumps based on existing infrastructure and predicted growth in both public and private sectors. A core focus is the intelligent integration of EV charging infrastructure to avoid local overloads and to optimise grid utilisation. Thereby municipally planned and privately driven expansion scenarios are compared, and grid bottlenecks are identified, proposing solutions through charge load management and targeted infrastructure upgrades. This study of Wüstenrot’s low-voltage grid reveals substantial capacity reserves for future integration of heat pumps, electric vehicles (EVs), and photovoltaic systems, supporting the shift to a sustainable energy system. While full-scale expansion would require significant infrastructure investment, mainly due to widespread EV adoption, simple measures like temporary charge load reduction could cut grid stress by up to 51%. Additionally, it is shown that bidirectional charging offers further relief and potential income for EV owners.

Keywords: Vehicle-to-Home; Vehicle-to-Grid; bidirectional charging; charge load management; grid simulation; e-mobility (search for similar items in EconPapers)
JEL-codes: Q Q0 Q4 Q40 Q41 Q42 Q43 Q47 Q48 Q49 (search for similar items in EconPapers)
Date: 2025
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