470966 Understanding the Transport of Gases in Carbon Molecular Sieve Using the Volumetric Frequency Response Technique

Tuesday, November 15, 2016: 3:55 PM
Cyril Magnin III (Parc 55 San Francisco)
Mohammad I. Hossain1, Armin D. Ebner2 and James A. Ritter2, (1)University of South Carolina, Columbia, SC, (2)Department of Chemical Engineering, University of South Carolina, Columbia, SC

Frequency response methods have been developed as an alternative technique for the determination of mass transfer mechanisms controlling the transport of gases into and out of microporous adsorbent materials. Recent results in the literature are showing that this technique seems to be the best for discriminating the controlling mechanism. It is also possible to reveal two or more different controlling mechanisms that may dominate in different frequency ranges. The present talk will focus on the use of the volumetric frequency response (VFR) approach for the identification on the main mechanism governing the transport of gases such as O2, N2 and CO2 in pelletized and ground molecular sieve carbon (MSC 3K 172 from Japan Enviro Chemicals, Osaka, Japan). In a recently commissioned VFR apparatus, experiments were carried out with pure gases at pressures of 200, 400 and 750 Torr, temperatures of 20, 30, 40 and 50 oC and frequencies between 0.7×10-5 and 10 Hz using pelletized CMS. Additional experiments were conducted at 750 Torr and 30 oC using a ground sample of this CMS with particle sizes between 30-50 Tyler mesh. The results are showing that the transport mechanism can be unequivocally identified when fitting the frequency response curves to various transport models. The results are also revealing that conducting FR experiments at different temperatures and pressures, as well as using different particle sizes helps to ensure that the correct transport mechanism has been identified. During this presentation the latest results obtained from the system will be presented and interpreted.

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See more of this Session: Diffusion, Transport and Dynamics in Adsorption Systems
See more of this Group/Topical: Separations Division