Cell-element simulations to optimize the performance of osmotic processes in porous membranes

Calo, V; Iliev, O; Nunes, S; Printsypar, G; Shi, M

Journal article

Cell-element simulations to optimize the performance of osmotic processes in porous membranes

Abstract:: We present a new module of the software tool PoreChem for 3D simulations of osmotic processes at the cell-element scale. We consider the most general fully coupled model (see e.g., Sagiv and Semiat (2011)) in 3D to evaluate the impact on the membrane performance of both internal and external concentration polarization, which occurs in a cell-element for different operational conditions. The model consists of the Navier–Stokes–Brinkman system to describe the free fluid flow and the flow within...
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Publication status:: Published

Peer review status:: Peer reviewed

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APA Style

Calo, V., Iliev, O., Nunes, S., Printsypar, G., & Shi, M. (2018). Cell-element simulations to optimize the performance of osmotic processes in porous membranes. Computers and Mathematics with Applications, 76(2), 361–376.

MLA Style

Calo, V., et al. “Cell-Element Simulations to Optimize the Performance of Osmotic Processes in Porous Membranes.” Computers and Mathematics with Applications, vol. 76, no. 2, Elsevier, 2018, pp. 361–76.

Chicago Style

Calo, V, O Iliev, S Nunes, G Printsypar, and M Shi. 2018. “Cell-Element Simulations to Optimize the Performance of Osmotic Processes in Porous Membranes.” Computers and Mathematics with Applications 76 (2): 361–76.
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Files:: CaloEtAl2018_accepted.pdf

(Accepted manuscript, pdf, 5.2MB)

Publisher copy:: 10.1016/j.camwa.2018.04.023

Authors

+ Calo, V More by this author

Role:

Author

+ Iliev, O More by this author

Role:

Author

+ Nunes, S More by this author

Role:

Author

+ Printsypar, G More by this author

Institution:

University of Oxford

Division:

MPLS

Department:

Mathematical Institute

Role:

Author

+ Shi, M More by this author

Role:

Author

Funding

+ King Abdullah University of Science and Technology More from this funder

Grant:

SABIC Postdoctoral Fellowship scheme

+ Russian Federation Government More from this funder

Grant:

Mega-grant 14.Y26.31.0013

+ European Union More from this funder

Grant:

InnovationProgramoftheMarieSklodowska-Curiegrant agreementNo.644202

Horizon2020Research

+ CSIRO More from this funder

Grant:

Deep Earth Imaging Enterprise Future Science Platforms of the Commonwealth Scientific Industrial Research Organisation, CSIRO, of Australia

Curtin Institute for Computation More from this funder

More funders...

Bibliographic Details

Publisher:: Elsevier Publisher's website
Journal:: Computers and Mathematics with Applications Journal website
Volume:: 76
Issue:: 2
Pages:: 361-376
Publication date:: 2018-05-11
Acceptance date:: 2018-04-20
DOI:: 10.1016/j.camwa.2018.04.023
ISSN:: 0898-1221

Item Description

Language:: English
Keywords:: mathematical modeling

heterogeneous and defective selective layer

forward osmosis

porous membranes

cell element
Pubs id:: pubs:844872
UUID:: uuid:aa040e73-cc60-4220-8b0b-a14ff706a305
Local pid:: pubs:844872
Source identifiers:: 844872
Deposit date:: 2018-04-30

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Copyright holder:: Elsevier Ltd

Licence:: CC Attribution-NonCommercial-NoDerivatives (CC BY-NC-ND)

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Journal article

Cell-element simulations to optimize the performance of osmotic processes in porous membranes

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