Pushing the limits of sodium borohydride hydrolysis for on-board hydrogen generation systems

Authors
Kirk, JaewonKim, YoondoLee, Yu-JinKim, MinkyuMin, Dong-SuKim, Pyung SoonSeo, Ji HuiKim, YongwooLee, JaeyongChoung, Jin WooSohn, HyuntaeNam, Suk-WooYoon, Chang-WonKim, YongminJeong, Hyangsoo
Issue Date
2023-06
Publisher
Elsevier BV
Citation
Chemical Engineering Journal, v.466
Abstract
Sodium borohydride (SBH) is a promising hydrogen (H2) carrier; however, its successful deployment has been limited to unmanned aerial vehicle applications. We reevaluated SBH hydrolysis for on-board vehicular appli-cations from an entirely new perspective using solid-phase SBH hydrolysis with a CO2-derived acid at elevated temperatures and pressures, enabling extremely efficient water utilization. This strategy afforded a high H2 storage density of 6.33 wt%, which could be extended to 10.4 wt% via water recovery from fuel cells. High -purity H2 with carbon monoxide levels below 10 ppm was obtained after methanation. Importantly, an energy-efficient SBH regeneration method using residual NaHCO2 was developed. A 1.2-kWe-level SBH hydrogen generation was evaluated with the fuel-cell operation, and a 20-kWe-level compact system was developed with a system-based volumetric H2 storage density of 25 g-H2/L. This technology will accelerate SBH-based vehicular applications at a level of 50 g-H2/L.
Keywords
FORMIC-ACID; GAS; DEHYDROGENATION; FUNDAMENTALS; METABORATE; CATALYST; VEHICLE; DESIGN; WATER; NABH4; Hydrogen production; Sodium borohydride; Formic acid; 20kW e -level H 2 generation system; Borax regeneration; Sodium borohydride value chain
ISSN
1385-8947
URI
https://pubs.kist.re.kr/handle/201004/113647
DOI
10.1016/j.cej.2023.143233
Appears in Collections:
KIST Article > 2023
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