Zenodo Community for publications and data from the FCH-JU project DOLPHIN.

Current PEMFC stack technologies for automotive applications have proven their competitiveness in terms of performance and durability. Reducing production costs is currently the main challenge for the mass production and commercialization of fuel cells and is therefore being intensively worked on by manufacturers and research institutions. In order to not only be competitive, but also to show the further potential of a new generation of fuel cells, the EU project DOLPHIN aims to implement an innovative, disruptive approach to a new cell architecture with a repeating unit reduced to two integrated core components.

The overall aim of the project is to validate disruptive technologies for 100 kW light-weight & compact fuel cell stack designs, reaching outstanding (specific & volumetric) power density while simultaneously featuring enhanced durability (under automotive application conditions) compared to state-of-the-art, and compatible with large scale/mass production of full power-stacks. For this purpose, innovative approaches in the areas of cell and stack design, manufacturing technology, process integration, interface quality, material efficiency and components are combined. In this way, an unprecedented power range (2 W/cm² active area) is to be achieved, which roughly doubles compared to the 2017 level.

Some facts:

• Acronym: DOLPHIN = Disruptive PEMFC stack with nOvel materiaLs, Processes, arcHitecture and optimized INterfaces.
• Start date 2019/01/01
• Duration: 4 years
• Call: H2020-JTI-FCH-2018-1
• Overall budget: € 2 962 681

KPIs:

• Power density > 2 W/cm2 at 0.66 V;
• Volumetric power density > 5 kW/l at nominal power;
• Specific power density > 4 kW/kg at nominal power;
• Durability: > 6,000 hours;
• Stack production cost < 20 €/kW (for > 100 000 units/year);
• Stack max operating temperature of 105 °C;

The project DOLPHIN has received funding from the Fuel Cells and Hydrogen 2 Joint Undertaking under grant agreement No. 826204. The JU receives support from the European Union's Horizon 2020 research and innovation programme and France, Germany, Austria, United Kingdom, Belgium, Switzerland.