Atlas / Learn / Papers / 20240013991
NASA NTRS · Poster
A Passive fuel-Cell Surface power System (PaCeSS)
Attribution
This is the abstract and citation. Full text lives at NASA NTRS — we link out rather than host. All credit to the authors and Johnson Space Center.
Abstract
Verbatim from NASA NTRS. Not paraphrased, not summarized.
This effort produces a fully-passive surface power generation capability for fuel cell technology. The concept replaces the actively pumped thermal management of a state of the art (SOA) fuel cell/electrolyzer stack with a passive 2-phase thermosyphon for heat transport and a passive shape memory actuating radiator for temperature management. The concept addresses NASA fuel cell technology roadmap needs for greater reliability and longer operating life by eliminating life limiting elements of SOA fuel cell system design that drive failure modes associated with moving parts and control complexity. Applications map to surface power (primary fuel cell), surface energy storage (regenerable fuel cell) and in-situ resource utilization (electrolyzer/unitized reversible fuel cell). The first year of this effort concluded with independent demonstrations of 2-phase thermosyphon heat transport from a simulated fuel cell and temperature driven actuation of a shape memory actuating radiator. Results are in-character with underlying physics and demonstrate the potential to realize the objectives of this concept. his effort produces a fully-passive surface power generation capability for fuel cell technology. The concept replaces the actively pumped thermal management of a state of the art (SOA) fuel cell/electrolyzer stack with a passive 2-phase thermosyphon for heat transport and a passive shape memory actuating radiator for temperature management.
Author
- Thomas Cognata Johnson Space Center
Keywords
- deionized water
- water polishing
- thermal management
- thermosyphon
- Fuel Cell
Citation: Thomas Cognata (2024). A Passive fuel-Cell Surface power System (PaCeSS). Johnson Space Center. NASA NTRS ID 20240013991. https://ntrs.nasa.gov/citations/20240013991 ↗