To overcome durability hurdle of polymer electrolyte membrane fuel cells (PEMFC) for heavy duty applications and in line with the Strategic Research and Innovation Agenda (SRIA) of the Clean Hydrogen Joint Undertaking, new application-tailored component materials, cell designs and operating strategies must be developed.
The purpose of the PEMSTATIC project which aims at bringing to technology readiness level (TRL) 4 the highly innovative concept of durable heavy-duty membrane electrode assembly (MEA) derived from enhanced degradation models and addressing the different sub-components of the catalyst coated membrane (CCM) and their interactions.
Specifically, PEMTASTIC aims to meet the key technical challenges to increase durability of membrane-electrode assembly (MEA) for heavy-duty applications. These challenges are approached with a combination of model-based design and the development of a durable catalyst coated membrane using innovative materials tailored for heavy duty operation at high temperature (105°C). The quantitative targets correspond to a durability of 20,000 hours maintaining a state-of the art power density of 1.2
W/cm2@0.65 V at a Pt loading of 0.30 g/kW.
The individual objectives of the project are:
Objective 1: Define fuel cell operation protocols and cycling tests for heavy duty application and propose operation strategy for high fuel efficiency.
Objective 2: Parameterisation of degradation models to predict MEA lifetime and identify specific improvements of the CCM and its components.
Objective 3: Development of robust catalyst support and deposition process for catalysts.
Objective 4: Development of membrane and ionomer for operation at increased temperature
Objective 5: Catalyst layers and CCM with increased durability and state-of-the art performance tailored for heavy duty operation
Objective 6: Ensure the dissemination of the project results and the promotion of the project, through ad-hoc strategies through target groups and key stakeholders and define the exploitation strategy of the PEMTASTIC outcome.