A two-dimensional flow model has been developed to simulate mass transport in a microchannel bioreactor with a porous wall. A two-domain approach, based on the finite volume method, was implemented. For the fluid part, the governing equation used was the Navier–Stokes equation; for the porous medium region, the generalized Darcy–Brinkman–Forchheimer extended model was used. For the porous-fluid interface, a stress jump condition was enforced with a continuity of normal stress, and the mass interfacial conditions were continuities of mass and mass flux. Two parameters were defined to characterize the mass transports in the fluid and porous regions. The porous Damkohler number is the ratio of consumption to diffusion of the substrates in the porous medium. The fluid Damkohler number is the ratio of the substrate consumption in the porous medium to the substrate convection in the fluid region. The concentration results were found to be well correlated by the use of a reaction-convection distance parameter, which incorporated the effects of axial distance, substrate consumption, and convection. The reactor efficiency reduced with reaction-convection distance parameter because of reduced reaction (or flux), and smaller local effectiveness factor due to the lower concentration in Michaelis–Menten type reactions. The reactor was more effective, and hence, more efficient with the smaller porous Damkohler number. The generalized results could find applications for the design of bioreactors with a porous wall.
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June 2010
Research Papers
Mass Transport in a Microchannel Bioreactor With a Porous Wall
Xiao Bing Chen,
Xiao Bing Chen
Dynamics Lab., E1–02–01, Department of Mechanical Engineering,
e-mail: mpecx@nus.edu.sg
National University of Singapore
, 1 Engineering Drive 2, Singapore 117576
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Yi Sui,
Yi Sui
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
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Heow Pueh Lee,
Heow Pueh Lee
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
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Hui Xing Bai,
Hui Xing Bai
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
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Peng Yu,
Peng Yu
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
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S. H. Winoto,
S. H. Winoto
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
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Hong Tong Low
Hong Tong Low
Department of Mechanical Engineering, Division of Bioengineering,
National University of Singapore
, Singapore 117576
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Xiao Bing Chen
Dynamics Lab., E1–02–01, Department of Mechanical Engineering,
National University of Singapore
, 1 Engineering Drive 2, Singapore 117576e-mail: mpecx@nus.edu.sg
Yi Sui
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
Heow Pueh Lee
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
Hui Xing Bai
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
Peng Yu
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
S. H. Winoto
Department of Mechanical Engineering,
National University of Singapore
, Singapore 117576
Hong Tong Low
Department of Mechanical Engineering, Division of Bioengineering,
National University of Singapore
, Singapore 117576J Biomech Eng. Jun 2010, 132(6): 061001 (12 pages)
Published Online: April 16, 2010
Article history
Received:
November 24, 2009
Revised:
January 8, 2010
Posted:
January 19, 2010
Published:
April 16, 2010
Online:
April 16, 2010
Citation
Chen, X. B., Sui, Y., Lee, H. P., Bai, H. X., Yu, P., Winoto, S. H., and Low, H. T. (April 16, 2010). "Mass Transport in a Microchannel Bioreactor With a Porous Wall." ASME. J Biomech Eng. June 2010; 132(6): 061001. https://doi.org/10.1115/1.4001044
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