| Title | Light Electric Vehicles for Muscle-Battery Electric Mobility in Circular Economy: A Comprehensive Study |
|---|---|
| ID_Doc | 29059 |
| Authors | Wuestenhagen, S; Beckert, P; Lange, O; Franze, A |
| Title | Light Electric Vehicles for Muscle-Battery Electric Mobility in Circular Economy: A Comprehensive Study |
| Year | 2021 |
| Published | Sustainability, 13.0, 24 |
| Abstract | Light electric vehicles (LEVs) facilitate a significant reduction in global warming potential (GWP) and other environmental impacts related to specific transport performance due to their lightweight construction. Low-voltage systems in the drive engine, an open vehicle design and online vehicle data processing allow LEVs to be repaired by independent workshops, thus enabling long vehicle use as well as conversion or retrofitting for periods of use beyond 20 years. LEVs are not yet very common in everyday life in Western Europe. In order to support the acceptance of muscle power-supported LEVs in the EU L7e registration class by users, the vehicle design and construction specifically address requirements in the areas of last-mile parcel delivery and other transport services, including passenger transport. Life cycle assessment was used to investigate two construction methods for LEVs, mixed construction and fibre composite construction, in terms of the production, service life phase and end of life. A vehicle configuration was developed which, in addition to resource-saving production and long-life operation, enables easy access for users and maintenance of the LEV for various purposes. The resource efficiency of light electric vehicles was proven with regard to the ecological aspects. The vehicle design shown here shows high potential for LEVs in the circular economy. |
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