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Fluid dynamic characterization of a fluidized‐bed perfusion bioreactor with CFD–DEM simulation
Author(s) -
Huang Zheqing,
Odeleye Akinlolu Oyekunle Oluseun,
Ye Hua,
Cui Zhanfeng,
Yang Aidong
Publication year - 2018
Publication title -
journal of chemical technology and biotechnology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.64
H-Index - 117
eISSN - 1097-4660
pISSN - 0268-2575
DOI - 10.1002/jctb.5576
Subject(s) - shear stress , computational fluid dynamics , mass transfer , fluidization , mechanics , cfd dem , fluidized bed , discrete element method , materials science , shear (geology) , mass transfer coefficient , particle (ecology) , particle size , superficial velocity , bioreactor , volume fraction , volume of fluid method , volume (thermodynamics) , chemistry , engineering , thermodynamics , chemical engineering , composite material , flow (mathematics) , waste management , geology , physics , oceanography , organic chemistry
BACKGROUND In the recent development of regenerative medicine, the low yields of progenitor cells have limited the large‐scale clinical applications. To overcome the limitation, a novel fluidized bed bioreactor has emerged. However, a detailed understanding of its fluid dynamics is still lacking. RESULTS A 3D modeling approach that couples computational fluid dynamics (CFD) and a discrete element method (DEM) was used to simulate the liquid and solid flows in a bioreactor being designed for stem cells expansion. The model was validated by comparing the simulation results with literature experimental data [ Chem Eng Sci 60 :1889–1900 (2005)], which showed a good agreement. Using the validated model, the effects of the superficial liquid velocity, particle size and particle density on the solids volume fraction, shear stress on the particles and liquid–solid mass transfer coefficient of dissolved oxygen and glucose were analyzed. CONCLUSIONS Simulation results show that particle size and density have an important impact on the shear stress distribution, and that the liquid velocity affects the shear stress distribution rather modestly when its value is beyond the minimum fluidization velocity. The liquid–particle mass transfer coefficient of dissolved oxygen and glucose can be improved by raising the liquid velocity, and the adoption of a high‐density material allows the reactor to operate with higher liquid velocities before reaching shear stress heterogeneities. Furthermore, the two objectives, (i) maintaining lower and homogeneously distributed shear stress and (ii) improving mass transfer, pose conflicting requirements on certain design parameters which need to be carefully considered in the reactor design. © 2018 Society of Chemical Industry