Numerical simulation of ion transport membrane reactors: Oxygen permeation and transport and fuel conversion

Author(s)

Hong, Jongsup; Kirchen, Patrick N.; Ghoniem, Ahmed F.

Abstract

Ion transport membrane (ITM) based reactors have been suggested as a novel technology for several applications including fuel reforming and oxy-fuel combustion, which integrates air separation and fuel conversion while reducing complexity and the associated energy penalty. To utilize this technology more effectively, it is necessary to develop a better understanding of the fundamental processes of oxygen transport and fuel conversion in the immediate vicinity of the membrane. In this paper, a numerical model that spatially resolves the gas flow, transport and reactions is presented. The model incorporates detailed gas phase chemistry and transport. The model is used to express the oxygen permeation flux in terms of the oxygen concentrations at the membrane surface given data on the bulk concentration, which is necessary for cases when mass transfer limitations on the permeate side are important and for reactive flow modeling. The simulation results show the dependence of oxygen transport and fuel conversion on the geometry and flow parameters including the membrane temperature, feed and sweep gas flow, oxygen concentration in the feed and fuel concentration in the sweep gas.

Date issued

2012-03

URI

http://hdl.handle.net/1721.1/103909

Department

Massachusetts Institute of Technology. Department of Mechanical Engineering

Journal

Journal of Membrane Science

Publisher

Elsevier

Citation

Hong, Jongsup, Patrick Kirchen, and Ahmed F. Ghoniem. "Numerical simulation of ion transport membrane reactors: Oxygen permeation and transport and fuel conversion." Journal of Membrane Science 407-408 (July 2012), pp. 71-85.

Version: Author's final manuscript

ISSN

03767388