Fuel cell drive for urban freight transport in comparison to diesel and battery electric drives: a case study of the food retailing industry in Berlin

John Kenneth Winkler; Alexander Grahle; Anne Magdalene Syré; Kai Martins-Turner; Dietmar Göhlich

doi:10.1186/s12544-022-00525-6

European Transport Research Review (Feb 2022)

Fuel cell drive for urban freight transport in comparison to diesel and battery electric drives: a case study of the food retailing industry in Berlin

John Kenneth Winkler,
Alexander Grahle,
Anne Magdalene Syré,
Kai Martins-Turner,
Dietmar Göhlich

Affiliations

John Kenneth Winkler: Chair of Methods for Product Development and Mechatronics, Technische Universität Berlin
Alexander Grahle: Chair of Methods for Product Development and Mechatronics, Technische Universität Berlin
Anne Magdalene Syré: Chair of Methods for Product Development and Mechatronics, Technische Universität Berlin
Kai Martins-Turner: Chair of Transport Systems Planning and Transport Telematics, Technische Universität Berlin
Dietmar Göhlich: Chair of Methods for Product Development and Mechatronics, Technische Universität Berlin

DOI: https://doi.org/10.1186/s12544-022-00525-6
Journal volume & issue: Vol. 14, no. 1
pp. 1 – 14

Abstract

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Abstract The option of decarbonizing urban freight transport using battery electric vehicle (BEV) seems promising. However, there is currently a strong debate whether fuel cell electric vehicle (FCEV) might be the better solution. The question arises as to how a fleet of FCEV influences the operating cost, the greenhouse gas (GHG) emissions and primary energy demand in comparison to BEVs and to Internal Combustion Engine Vehicle (ICEV). To investigate this, we simulate the urban food retailing as a representative share of urban freight transport using a multi-agent transport simulation software. Synthetic routes as well as fleet size and composition are determined by solving a vehicle routing problem. We compute the operating costs using a total cost of ownership analysis and the use phase emissions as well as primary energy demand using the well to wheel approach. While a change to BEV results in 17–23% higher costs compared to ICEV, using FCEVs leads to 22–57% higher costs. Assuming today’s electricity mix, we show a GHG emission reduction of 25% compared to the ICEV base case when using BEV. Current hydrogen production leads to a GHG reduction of 33% when using FCEV which however cannot be scaled to larger fleets. Using current electricity in electrolysis will increase GHG emission by 60% compared to the base case. Assuming 100% renewable electricity for charging and hydrogen production, the reduction from FCEVs rises to 73% and from BEV to 92%. The primary energy requirement for BEV is in all cases lower and for higher compared to the base case. We conclude that while FCEV have a slightly higher GHG savings potential with current hydrogen, BEV are the favored technology for urban freight transport from an economic and ecological point of view, considering the increasing shares of renewable energies in the grid mix.

Published in European Transport Research Review

ISSN: 1867-0717 (Print); 1866-8887 (Online)
Publisher: SpringerOpen
Country of publisher: United Kingdom
LCC subjects: Technology: Engineering (General). Civil engineering (General): Transportation engineering; Social Sciences: Transportation and communications
Website: https://etrr.springeropen.com

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