Periodic Reporting for period 4 - FLHYSAFE (Fuel CelL HYdrogen System for AircraFt Emergency operation)
Berichtszeitraum: 2022-07-01 bis 2023-06-30
The preliminary design of the electrical and power management system in charge of powering all the electrical consumers (sensors, actuators and Aircraft loads) was performed through the analysis of the electrical load. The EPMS preliminary architecture and voltage buses were frozen and converters entered in detailed design phase.
This work allowed the consortium to choose between two high level architectures: an initially planned H2/air architecture or the finally chosen innovative H2/O2 architecture taking profit of next-generation aircrafts that encourages FCS engineers to use new aircraft interfaces for cooling and fuel supply - making systems much simpler that positively affects their reliability and hence makes the technology more attractive for the market.
An FC sub-system adapted to airborne applications was designed and developed. Assembly tooling adapted to FC stacks were designed and manufactured. Tests on short stack fed with O2 instead of air were performed to mitigate risks associated to oxidant choice and to optimise stack sizing.
A 0D FC model was developed and implemented to simulate the EPU system activity. This model translates stack behaviour under various operating conditions. A good fitting with experimental results was achieved. Start/stop study was conducted by applying start-up and shutdown protocol for 466 cycles, allowing conducting a mathematical analysis of the stack degradation (stack power evolution as a function of the number of start/stop cycles).
The integrated converter and its electronics, mechanics and thermics parts were designed. The electronic boards, inductors and mechanical parts were manufactured. Electronic boards were tested on a prototype version to easily adjust the HW and the SW. The assembly of the integrated version was successfully tested.
Based on the mature EPU architecture obtained during the study phases, architectures of the Low Temperature Module (FCS-a) and the FLHYSAFE demonstrator (FCS-b) were frozen. This allowed the consortium to: complete the detailed design of both systems; start the manufacturing and the assembly of the FCS-a; perform initial tests: power management table, monitoring and control, auxiliary and integrated converter tests were performed successfully; start the assembly of the FCS-b.
The tests of the sub-parts (anode, cathode, FCS-a) were conducted with mixed results. The tests done on cathode and anode loop allowed a good knowledge capitalization for the operational tests on the demonstrator. On the other hand, the stack was damaged but the control system for the operational tests could be validated and updated.
The final stack and the demonstrator were assembled, the operational tests were conducted. The demonstrator operation up to 6kW was validated despite a stack failure occurring during the test campaign. Environmental test campaign reduction scope and delay due to failure of the stack led to a short vibration test campaign with positive results.
In parallel to the technical activities, transversal activities were performed: a cost analysis ownership study concluded that the FC market in aeronautics is not mature and needs to develop to be competitive with the RAT.
The development of a Virtual Reality tool to create Assembly and Maintenance tasks and procedures through VR manipulations was achieved. The projection of the system in VR environment is functional, leading to program assembly task scenarios and perform them in VR for validation or training. The first maintenance procedures drafts were achieved.
While the scientific activities of the project were progressing, FLHYSAFE partners conducted dissemination activities to raise awareness of the project: public website and social media accounts were regularly updated to present the project events and results.
FLHYSAFE contributed to a better understanding of FC technology in various areas: maturity in FC stack parts manufacturing (metallic bipolar plate, sealing) enhanced by French industrial supply chain; understanding of pure O2 use in aeronautics; development of an interesting option with a DCDC to tackle integration challenges.
As next steps, after the project end, the consortium members will continue to work on:
• The weak point of the developed EPU architecture will be addressed by DLR in future projects
• A new converter receiving FC stack voltage will be studied by CEA
• INTA will develop tests facilities for anode and cathode test in altitude
• SPU will focus on FC product for non-propulsive and propulsive aeronautical application to achieve Europe aeronautical decarbonation target.