Abstract
Hybridization of diesel multiple unit railway vehicles is an effective approach to reduce fuel consumption and related emissions in regional non-electrified networks. This paper is part of a bigger project realized in collaboration with Arriva, the largest regional railway undertaking in the Netherlands, to identify optimal solutions in improving trains’ energy and environmental performance. A significant problem in vehicle hybridization is determining the optimal size for the energy storage system, while incorporating an energy management strategy as well as technical and operational requirements. With the primary requirement imposed by the railway undertaking to achieve emission-free and noise-free operation within railway stations, we formalize this as a bi-level multi-objective optimization problem, including vehicle performance, the trade-off between fuel savings and hybridization cost, influence of the energy management strategy, and other constraints. By deriving a Li-ion battery parameters at the cell level, a nested coordination framework is employed, where a brute force search finds the optimal battery size using dynamic programming for full controller optimization for each feasible solution. In this way, the global minimum for fuel consumption for each battery configuration is achieved. The results from a Dutch case study demonstrated fuel savings and CO2 emission reduction of more than 34% compared to a standard vehicle. Additionally, benefits in terms of local pollutants (NOx and PM) emissions are observed. Using an alternative sub-optimal rule-based control demonstrated a significant impact of the energy management on the results, reflected in higher fuel consumption and increased battery size together with corresponding costs.
Highlights
Air pollution is of great concern in politics, the scientific community, industry, and society in general
Focusing on a case study of regional railway services provided by Arriva on the Northern lines in the Netherlands, this paper proposes an integrated optimization of energy storage system (ESS) size and energy management strategy (EMS), considering conventional diesel multiple units (DMU) vehicles from the Dutch network converted to their hybrid counterpart
Estimation of the fuel consumption and related emissions of con ventional DMU is done by evaluating the model in Fig. 2, with the total requested power provided by internal combustion engines (ICE)
Summary
Air pollution is of great concern in politics, the scientific community, industry, and society in general. The global warming effect caused by greenhouse gasses (GHG) and especially carbon dioxide (CO2) emissions from anthropogenic sources led to various international treaties, such as the Kyoto Protocol [1] and the follow-up Paris Agreement [2], resulting in recommendations and defined targets to reduce the emissions. The transport sector is one of the most significant contrib utors to GHG emissions and targets have been defined for transportation systems at all levels. In the case of the railway sector, targets were set in 2008 by the International Union of Railways (UIC) and the Community of European Railway and Infrastructure Companies tudelft.nl (R.M.P. Goverde)
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