The Role of Powertrain Electrification in Achieving Deep Decarbonization in Road Freight Transport

Juan C González Palencia,Van Tuan Nguyen,Seiichi Shiga,Mikiya Araki

doi:10.3390/en13102459

Juan C González Palencia, Van Tuan Nguyen + Show 2 more

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https://doi.org/10.3390/en13102459

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Journal: Energies	Publication Date: May 13, 2020
Citations: 24	License type: CC BY 4.0

Affiliation: Gunma University

Abstract

Decarbonizing road freight transport is difficult due to its reliance on fossil fuel internal combustion engine vehicles (ICEVs). The role of powertrain electrification in achieving deep decarbonization in road freight transport was studied using a vehicle stock turnover model, focusing on Japan. Twelve vehicle types were considered; combining four powertrains, ICEV, hybrid electric vehicle (HEV), battery electric vehicle (BEV) and fuel cell electric vehicle (FCEV); and three vehicle size classes, normal, compact and mini-sized vehicles. A scenario-based approach was used; considering a Base scenario, and three alternative scenarios targeting powertrain electrification. Between 2012 and 2050, tank to wheel CO2 emissions decrease 42.8% in the Base scenario, due to the reduction of vehicle stock, the improvement of vehicle fuel consumption and the adoption of HEVs. Diffusion of FCEVs in normal vehicles and BEVs in compact and mini-sized vehicles achieves the largest tank to wheel CO2 emissions reductions, up to 44.6% compared with the 2050 baseline value. The net cash flow is positive over the whole time horizon, peaking at 6.7 billion USD/year in 2049 and reaching 6.6 billion USD/year by 2050. Powertrain electrification is not enough to achieve any of the CO2 emissions reduction targets in road freight transport.

Highlights

IntroductionRoad freight transport accounts for a significant share of global energy consumption in the transport sector
A vehicle stock turnover model of the road freight vehicle fleet was used to assess the role of powertrain electrification in the decarbonization of road freight transport in the case of Japan between
Driven by the reduction of the vehicle stock, the improvement of vehicle fuel consumption and the adoption of hybrid electric vehicle (HEV), energy consumption and CO2 emissions decrease around 42% between

Summary

Introduction

Road freight transport accounts for a significant share of global energy consumption in the transport sector. Almost 45% of global transport energy consumption corresponds to freight transport, with heavy-duty vehicles (HDVs) using more than half of that energy [1]. Road freight transport depends heavily on fossil fuels; with medium freight trucks and heavy freight trucks accounting for 24% of global oil-based fuel consumption [2]. Diesel is the main fuel used in road freight transport, accounting for 84% of all oil products used; and corresponding to half of the global diesel demand [3]. Road freight vehicles are difficult to characterize due to the variety of vocational uses that requires a large number of sizes and configurations. One additional difficulty for road freight vehicle characterization is that criteria for vehicle size classification vary depending on the country or region

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