“The decision to move to metal bipolar plates allowed us to leverage a lot of know how from the automotive industry’s large investment in hydrogen fuel cells” said Dr. Benjamin Gould, NRL’s chief scientist on the project. “Using the plates also enabled enhanced storage capabilities and weight savings that are critical for naval unmanned system applications.”
The bipolar plates, held together with titanium straps, serve as the structural backbone of the fuel cell system, providing fluidic pathways for air, hydrogen, and coolant along with electronic pathways for conduction between the individual cells.
NRL also contributed a custom microcontroller and lightweight air compressor. Gas and coolant flow fields were designed and validated with NRL’s own computational fluid design suite.
“NRL having the know how to build their own fuel cells in house gives ONR and the U.S. Navy the understanding and tools needed for transitioning fuel cells to the fleet,” said Michele Anderson, program manager at the Office of Naval Research.
Creating components at NRL allows for low-cost modular systems for both prototype development of naval unmanned vehicles and scalability to a range of sizes.