TY - JOUR
T1 - A compact non-PGM catalytic hollow fibre converter for on-board hydrogen production
AU - Mazzone, Simona
AU - Leishman, Claire
AU - Zhang, G.
AU - Garcia Garcia, Francisco
N1 - Funding Information:
The prolegomena of this work were presented as a communication in the IV UKEM Workshop in October 2020 (https://emissioncontrolukem.wordpress.com/). S. Mazzone would like to thank all who attended that session for their helpful comments and discussion. Moreover, S. Mazzone gratefully acknowledges the funding provided by the School of Engineering at the University of Edinburgh to carry out her PhD. Likewise, C. Leishman gratefully acknowledges the funding provided by the School of Engineering at the University of Edinburgh during her Summer Vacation Internship at the Denbigh Lab in Jun-Aug 2019. Finally, F. R. García-García would like to thank Joseph El-Kadi, and Catalysis and Process Integration Group at the University of Cambridge, for their help and support in the TPR experiments.
Publisher Copyright:
This journal is © The Royal Society of Chemistry
PY - 2022/3/21
Y1 - 2022/3/21
N2 - Hollow fibre-based converters offer an outstanding solution for on-board hydrogen production via ammonia decomposition, representing a more compact, efficient and affordable alternative to traditional packed bed reactors. In this work, Co/Mo-based catalysts supported on three different carbon xerogels were tested during the ammonia decomposition reaction. Co/Mo-NCX, which exhibited the best catalytic performance, was selected to be deposited inside the hollow fibre substrate. At 500 °C and 1 atm the hollow fibre converter was 3.6 times more efficient than the packed bed reactor (i.e. rNH3 = 5.5 × 104 molNH3 m−3 h−1 gcat−1 and rNH3 = 1.5 × 104 molNH3 m−3 h−1 gcat−1, respectively). This can be explained by narrower residence time distribution and minimised mass transfer limitations of the hollow fibre converter. Moreover, the hollow fibre converter showed a noticeably high thermal stability and catalyst-preservability during a 300 h reaction run. Furthermore, it exhibited a significantly lower pressure drop (i.e. >99%), volume (i.e. 70% less) and catalyst loading (i.e. 60% less) compared to the packed bed reactor. On this basis, the hollow fibre converter is especially suitable for on-board hydrogen production in automobiles, where space constraints present a key challenge. The potential of this new technology is enormous, since it will facilitate safe on-board hydrogen production, which is a key step in the decarbonisation of the transport sector in the fuel scenario nowadays.
AB - Hollow fibre-based converters offer an outstanding solution for on-board hydrogen production via ammonia decomposition, representing a more compact, efficient and affordable alternative to traditional packed bed reactors. In this work, Co/Mo-based catalysts supported on three different carbon xerogels were tested during the ammonia decomposition reaction. Co/Mo-NCX, which exhibited the best catalytic performance, was selected to be deposited inside the hollow fibre substrate. At 500 °C and 1 atm the hollow fibre converter was 3.6 times more efficient than the packed bed reactor (i.e. rNH3 = 5.5 × 104 molNH3 m−3 h−1 gcat−1 and rNH3 = 1.5 × 104 molNH3 m−3 h−1 gcat−1, respectively). This can be explained by narrower residence time distribution and minimised mass transfer limitations of the hollow fibre converter. Moreover, the hollow fibre converter showed a noticeably high thermal stability and catalyst-preservability during a 300 h reaction run. Furthermore, it exhibited a significantly lower pressure drop (i.e. >99%), volume (i.e. 70% less) and catalyst loading (i.e. 60% less) compared to the packed bed reactor. On this basis, the hollow fibre converter is especially suitable for on-board hydrogen production in automobiles, where space constraints present a key challenge. The potential of this new technology is enormous, since it will facilitate safe on-board hydrogen production, which is a key step in the decarbonisation of the transport sector in the fuel scenario nowadays.
U2 - 10.1039/d2se00122e
DO - 10.1039/d2se00122e
M3 - Article
SN - 2398-4902
VL - 6
SP - 1554
EP - 1567
JO - Sustainable Energy & Fuels
JF - Sustainable Energy & Fuels
IS - 6
ER -