Column absorption for reproducible cyclic separation in small scale ammonia synthesis

Citation data:

AIChE Journal, ISSN: 0001-1541, Vol: 63, Issue: 7, Page: 3058-3068

Publication Year:
2017
Usage 13
Abstract Views 13
DOI:
10.1002/aic.15685
Author(s):
Kevin Wagner, Mahdi Malmali, Collin Smith, Alon McCormick, E. L. Cussler, Ming Zhu, Nicholas C. A. Seaton
Publisher(s):
Wiley-Blackwell
Tags:
Biochemistry, Genetics and Molecular Biology, Environmental Science, Chemical Engineering
article description
Ammonia is rapidly and reversibly absorbed on magnesium chloride supported on alumina. The absorption at ambient temperature is twice that on alumina alone, but much of the ammonia is still captured at 400°C, closer to the temperature of ammonia synthesis. Regeneration at 450°C is complete in 30 min; partial regeneration is faster, and is correlated with the temperature and the regeneration time. The supported absorbent column works for many cycles, reproducibly, because submicron-sized MgClcrystals are trapped in similarly sized pores in the alumina itself, and the confinement prevents deterioration of the microstructure during absorption or regeneration. In contrast, while ammonia absorption into pure magnesium chloride is potentially much larger at equilibrium, the ammonia absorbs very slowly, and the chloride loses available capacity with use, probably because of fusing and deterioration of microstructure. A simplified model was constructed to simulate ammonia absorption into pure magnesium chloride and alumina-supported magnesium chloride. © 2017 American Institute of Chemical Engineers AIChE J, 63: 3058–3068, 2017.

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