Electrical Infrastructure Design Methodology of Dynamic and Static Charging for Heavy and Light Duty Electric Vehicles

Abstract: Full electrification of the transport sector is a necessity to combat climate change and a pressing societal issue: climate agreements require a fuel shift of all the modes of transport, but while uptake of passenger electric vehicles is increasing, long haul trucks rely almost completely on fossil fuels. Providing highways with proper charging infrastructure for future electric mobility demand is a problem that is not fully investigated in literature: in fact, previous work has not addressed grid planning and… Show more

“…In [94], authors carried out a test in a laboratory facility (by a renown automotive house) and verified an efficiency (DC power transmission) range between 86% and 90%. Recently, authors in [95] reviewed the technical characteristics of dynamic solutions implemented in pilots around the world. Researchers simulated the mobility demand of a highway in Norway (both for light and heavy duty vehicles) to ultimately design an electric infrastructure for both static and inductive charging infrastructures.…”

Planning of High-Power Charging Stations for Electric Vehicles: A Review

“…In [94], authors carried out a test in a laboratory facility (by a renown automotive house) and verified an efficiency (DC power transmission) range between 86% and 90%. Recently, authors in [95] reviewed the technical characteristics of dynamic solutions implemented in pilots around the world. Researchers simulated the mobility demand of a highway in Norway (both for light and heavy duty vehicles) to ultimately design an electric infrastructure for both static and inductive charging infrastructures.…”

Planning of High-Power Charging Stations for Electric Vehicles: A Review

Beyond predict and provide: Embracing sufficiency synergies in road freight electrification across the European Union

Battery electric long-haul trucks in Europe: Public charging, energy, and power requirements