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Full-battery effect during on-board solar charging of conventional vehicles

Chiara Lodi, Susana Gil-Sayas, Davide Currò, Simone Serra, Yannis Drossinos

2021Transportation Research Part D Transport and Environment13 citationsDOIOpen Access PDF

Abstract

On-board photovoltaic arrays may reduce fuel consumption and contribute to decarbonization of road transport by feeding the electric storage capacity of a vehicle. Since the CO2 savings arising from this technology cannot be quantified by standard test-cycle CO2 measurements, additional procedures are considered to assess its performance under real-world driving. The full-battery effect, i.e., the loss of potentially storable solar energy due to battery saturation, influences significantly these savings. The objective of this study is to present a novel methodology to evaluate the impact of the full-battery effect during on-board solar charging of conventional vehicles and thereby to estimate the associated CO2 savings. The methodology is based on solar irradiance and driver mobility data. Results show that the full-battery effect can be uniquely determined by the normalized real-world solar irradiance and two dimensionless combinations of vehicle electric power consumption, solar-energy storage capacity, system efficiency, PV array peak power and inclination.

Topics & Concepts

Photovoltaic systemAutomotive engineeringBattery (electricity)Solar irradianceIrradianceElectric vehicleSolar energyAutomotive batteryEnvironmental scienceFuel efficiencyBattery capacityElectrical engineeringEngineeringPower (physics)MeteorologyQuantum mechanicsPhysicsElectric Vehicles and InfrastructureVehicle emissions and performanceAdvanced Battery Technologies Research
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