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Abstract
Many public transport authorities have a great interest in introducing zero-emission electric buses. However, the transformation process from diesel to electric bus systems opens up a vast design space which seems prohibitive for a systematic decision making process. We present a holistic design methodology to identify the ‘most suitable system solution’ under given strategic and operational requirements. The relevant vehicle technologies and charging systems are analysed and structured using a morphological matrix. A modular simulation model is introduced which takes technical and operational aspects into account. The model can be used to determine a feasible electric bus system. The technology selection is based on a detailed economic analysis which is conducted by means of a total cost of ownership (TCO) model. To cope with uncertainties in forecasting, a stochastic modelling of critical input parameters is applied and three different future scenarios are evaluated. The applicability of the model was verified in a pilot project in Berlin and the methodology was applied to a realistic operational scenario. Our results indicate that electric bus systems are technically feasible and can become economically competitive from the year 2025 under the conditions examined.
Highlights
This study presents a holistic design methodology for urban electric bus systems based on technical feasibility assessment and total cost of ownership (TCO) as a key performance indicator
Based on the pre-selection shown in Section 5, the TCO assessment is conducted for two Opportunity charging (OC) cases, one Depot charging (DC) case and standard diesel buses as a reference case
With the help of a verified modular simulation model, the vast variety of theoretical system solutions can be reduced to a subset of technically feasible variants
Summary
We will give an overview of relevant components in electric bus systems and discuss the technical parameters most important for electric bus system design. The studies FCH JU (2012) and Roland (2015) predict an approximate cost parity for fuel cell and conventional diesel buses not before the year 2030; whereas, battery-electric buses are promising to achieve cost savings considerably earlier in time. Even with this reduced number of options we still face the need for a methodical identification of a ‘most suitable system solution’ under given strategic and operational requirements
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