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Investigation of membrane fouling in cross flow microfiltration of non-alcoholic beer and modeling of tubular membrane flow

Hajipour, M ; Sharif University of Technology | 2010

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  1. Type of Document: Article
  2. DOI: 10.1016/j.desal.2009.10.005
  3. Publisher: 2010
  4. Abstract:
  5. In the present work, numerical simulation of cross flow microfiltration of non-alcoholic beer in a tubular membrane has been studied theoretically and verified experimentally. Finite element method was used as a powerful tool for simulation. The feed stream, which flows mainly tangentially to the porous membrane surface, is modeled by the Navier-Stokes equations whereas the porous wall conditions are described by the Darcy equation that relates the pressure gradient within a flow stream to the flow rate through the permeable wall. A new model that considers transient behavior of the membrane due to fouling was used to estimate the permeate flux reduction. A pilot-scale cross flow membrane filter was developed to verify the model results in which ceramic tubular membranes were used. The cross flow velocity of the feed solution was controlled in the laminar region. It was shown that the model results have good agreement with experimental observations and therefore the model developed in this work can be used for design or optimization of the microfiltration of non-alcoholic beer
  6. Keywords:
  7. Non-alcoholic beer ; Tubular membrane ; Crossflow membranes ; Crossflow microfiltration ; Crossflow velocities ; Darcy equations ; Experimental observation ; Feed solution ; Feed streams ; Flow streams ; Model results ; New model ; Numerical simulation ; Permeable wall ; Permeate flux ; Pilot scale ; Porous membranes ; Porous walls ; Transient behavior ; Tubular membranes ; Beverages ; Ceramic membranes ; Clarification ; Clarifiers ; Computer simulation ; Hydraulics ; Membrane fouling ; Microfiltration ; Navier Stokes equations ; Finite element method ; Experimental study ; Filtration ; Fouling ; Membrane ; Numerical model ; Optimization
  8. Source: Desalination ; Volume 251, Issue 1-3 , 2010 , Pages 20-28 ; 00119164 (ISSN)
  9. URL: http://www.sciencedirect.com/science/article/pii/S001191640901203X