Half of the railway lines in the European Union are electrified and already enable local emission-free rail transport. Diesel-powered trains are used on the remaining sections of the lines. In the EU project FCH2RAIL (Fuel Cell Hybrid Power Pack for Rail Applications), the consortium is developing and testing a new type of train prototype with partners from Belgium, Germany, Spain and Portugal: At the heart of the project is a hybrid, bi-modal drive system that combines the electrical power supply from the overhead line with a hybrid power pack consisting of fuel cells and batteries that is independent of the overhead line.

Overhead line and hybrid system: Bi-modal, emission-free travelling

The basic idea: Where energy is available from overhead lines, the train continues to run on it. Where there are no overhead lines, the energy comes from the fuel cell battery system, the "Fuel Cell Hybrid Power Pack". "We want to show that this type of bi-mode power pack is a competitive and environmentally friendly alternative to diesel power", describes project leader and researcher Holger Dittus from the German Aerospace Center - Institute of Vehicle Concepts (DLR).

Across Europe, more and more railway lines are being electrified, i.e. equipped with overhead lines. A very expensive and long-term project that always depends on the local geographical conditions. Purely battery-powered trains have a limited range of 30 to 70 kilometres, depending on the route profile and outside temperatures. Today's diesel trains have restrictions in speed and acceleration compared to vehicles powered from overhead lines. "Our bi-modal fuel cell battery system combines the advantages of both technologies. This lets us make rail transport even more sustainable and energy-efficient", says Eva Terron, Technical Project Manager at Construcciones y Auxiliar de Ferrocarriles (CAF), summarising the main goal of the project.

With a budget of 14 million euros, the project aims to develop, demonstrate and approve such a system within the next four years. The project is funded with 10 million euros by the Fuel Cells and Hydrogen 2 Joint Undertaking (FCH 2 JU).


Scalable drive unit for efficient production

The energy supply system is to be designed in such a way that power and range can be expanded based on a modular principle: The number of fuel cell and battery modules influences the drive power, the number of hydrogen tanks determines the range on non-electrified lines. This way, the drive unit can be designed for use in both passenger and freight transport. This design also makes it possible to produce the required components in greater numbers and thus more cost-effectively.

 

Put on track: Functional tests with converted commuter train

Which railway lines are suitable for trial runs in Spain and Portugal? And what are the environmental impacts of such a system, from its production, to its use, up to its disposal? To answer these question in a test under real conditions, it is planned to convert a CIVIA electric commuter train from the Spanish manufacturer CAF and to integrate a fuel cell hybrid power pack. The Spanish state railway company Renfe Operadora is providing the train. The central components are fuel cell systems from Toyota Motor Europe (TME). Initial functional tests and trial runs for approval are to take place on Spanish and Portuguese tracks with the support of the infrastructure managers Administrador de Infrastructuras Ferroviarias (ADIF) and Infraestruturas de Portugal (IP). The Spanish hydrogen research centre Centro National de Hidrogeno (CNH2) has been entrusted with the construction of a hydrogen fuelling station to refuel the prototype.

 

Designing and controlling the system, energy management and homologation


Up until the first trial runs, the international project team still has a number of technological challenges to solve: For the design, fuel cell and battery modules must be combined and controlled in such a way that the system meets all requirements and can be implemented cost-effectively at the same time. In addition, it should be possible to use the waste heat from the fuel cell as cleverly as possible to heat and air-condition the train. The air conditioning manufacturer Faiveley / Stemmann Technik (STT) and DLR are investigating innovative solutions for reducing the energy demand for heating, ventilation and air conditioning (HVAC) as part of the project. In addition Stemmann analyses the interaction of the pantograph system with hydrogen systems.

Another critical issue is the safe interaction of hydrogen technology and overhead catenary at all times: This is because hydrogen is a highly volatile and reactive gas, and overhead catenaries can occasionally cause a spark. The project therefore examines norms and standards in the fields of hydrogen and rail transport and attempts to bring the two together. Based on this, the project team is developing proposals for approval authorities so that such trains can be approved more easily across the EU in the near future.

 

Duration

01/2021 - 12/2024

 

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