(351bc) Carbon Molecular Sieve Hollow Fiber Membranes for High Purity Oxygen Production | AIChE

(351bc) Carbon Molecular Sieve Hollow Fiber Membranes for High Purity Oxygen Production

Authors 

Seong, J. G. - Presenter, Hanyang University
Lewis, J. - Presenter, University of North Dakota
Matteson, J., Los Alamos National Laboratory
Baca, J., University of New Mexico
Josephson, A. J., Brigham Young University
Russell, C., Brigham Young University
Holland, T., Los Alamos National Laboratory
Kress, J., Los Alamos National Lab
Berchtold, K. A., Los Alamos National Laboratory
Singh, R. P., Los Alamos National Laboratory
Hydrocarbon fuel combustion in oxygen enriched air (OEA) is studied as a pathway to improve energy efficiency of carbon capture process. Membrane technology is a good alternative to industry standard cryogenic methods for OEA production owing to their practical merits including continuous process operations, good scalability, and cost-effectiveness with small footprint. In particular, carbon molecular sieve (CMS) membranes have gained attention for gas separation including air separations. The gas separation performance of the CMS membranes can be controlled for specific gas pairs (e.g. O2/N2, CO2/CH4, H2/CO2) to meet application specific needs with proper polymer precursors selections and programmable pyrolysis protocols. Here, we explore CMS hollow fiber membranes (HFMs) prepared from rigid and rod-like aromatic polybenzimidazole (PBI) materials for OEA productions. PBI mambrane material highly-packed interchain configurations endowed the resulting CMS HFMs with more oxygen selective characteristics than previously reported CMS membranes derived from other polymers. Comprehensive investigations of pyrolysis protocols for highly oxygen selective PBI-based CMS HFM fabrications and their performance relationships will be discussed. In addition, practical feasiblity of energy efficient OEA productions using CMS HFMs is assessed via process modelling simulations with the selected performance data.