Design of robust hollow fiber membranes with high power density for osmotic energy production

Handle URI:
http://hdl.handle.net/10754/563470
Title:
Design of robust hollow fiber membranes with high power density for osmotic energy production
Authors:
Zhang, Sui; Sukitpaneenit, Panu; Chung, Neal Tai-Shung ( 0000-0003-3704-8609 )
Abstract:
This study highlights the design strategy of highly asymmetric hollow fiber membranes that possess both characteristics of high flux and high mechanical strength to effectively reap the osmotic energy from seawater brine with an ultrahigh power density. An advanced co-extrusion technology was employed to fabricate the polyethersulfone (PES) hollow fiber supports with diversified structures from macrovoid to sponge-like. The microstructure of the supports is found critical for the stability and water permeability of the thin film composite (TFC) membranes. A high porosity in the porous layer is needed to reduce internal concentration polarization, while a thick and relatively dense skin layer underneath the TFC layer is required to maintain good mechanical stability and stress dissipation. The pore size of the supporting layer underneath the TFC layer must be small with a narrow pore size distribution to ensure the formation of a less-defective, highly permeable and mechanically stable TFC layer. The newly developed hollow fiber comprising high asymmetry, high porosity, and a thick skin layer with a small and narrow pore size distribution underneath the TFC layer produces a maximum power density of 24.3W/m2 at 20.0bar by using 1M NaCl as the concentrated brine and deionized (DI) water as the feed. The proposed design strategy for ultrahigh power density membranes clearly advances the osmotic energy production close to commercialization with a quite cost-effective and practicable approach. © 2013 Elsevier B.V.
KAUST Department:
Water Desalination and Reuse Research Center (WDRC)
Publisher:
Elsevier BV
Journal:
Chemical Engineering Journal
Issue Date:
Apr-2014
DOI:
10.1016/j.cej.2013.10.063
Type:
Article
ISSN:
13858947
Sponsors:
This research was funded by the Singapore National Research Foundation under its Competitive Research Program for the project entitled, "Advanced FO Membranes and Membrane Systems for Wastewater Treatment, Water Reuse and Seawater Desalination" (Grant Number: R-279-000-336-281) and was also supported by the Singapore National Research Foundation under its Environmental 81 Water Technologies Strategic Research Programme and administered by the Environment & Water Industry Programme Office (EWI) of the PUB under the project titled "Membrane Development for Osmotic Power Generation, Part 1. Materials Development and Membrane Fabrication" (1102-IRIS-11-01) and NUS Grant No. R-279-000-381-279. The authors would like to thank Mr. Wang Peng for his suggestions.
Appears in Collections:
Articles; Water Desalination and Reuse Research Center (WDRC)

Full metadata record

DC FieldValue Language
dc.contributor.authorZhang, Suien
dc.contributor.authorSukitpaneenit, Panuen
dc.contributor.authorChung, Neal Tai-Shungen
dc.date.accessioned2015-08-03T11:52:18Zen
dc.date.available2015-08-03T11:52:18Zen
dc.date.issued2014-04en
dc.identifier.issn13858947en
dc.identifier.doi10.1016/j.cej.2013.10.063en
dc.identifier.urihttp://hdl.handle.net/10754/563470en
dc.description.abstractThis study highlights the design strategy of highly asymmetric hollow fiber membranes that possess both characteristics of high flux and high mechanical strength to effectively reap the osmotic energy from seawater brine with an ultrahigh power density. An advanced co-extrusion technology was employed to fabricate the polyethersulfone (PES) hollow fiber supports with diversified structures from macrovoid to sponge-like. The microstructure of the supports is found critical for the stability and water permeability of the thin film composite (TFC) membranes. A high porosity in the porous layer is needed to reduce internal concentration polarization, while a thick and relatively dense skin layer underneath the TFC layer is required to maintain good mechanical stability and stress dissipation. The pore size of the supporting layer underneath the TFC layer must be small with a narrow pore size distribution to ensure the formation of a less-defective, highly permeable and mechanically stable TFC layer. The newly developed hollow fiber comprising high asymmetry, high porosity, and a thick skin layer with a small and narrow pore size distribution underneath the TFC layer produces a maximum power density of 24.3W/m2 at 20.0bar by using 1M NaCl as the concentrated brine and deionized (DI) water as the feed. The proposed design strategy for ultrahigh power density membranes clearly advances the osmotic energy production close to commercialization with a quite cost-effective and practicable approach. © 2013 Elsevier B.V.en
dc.description.sponsorshipThis research was funded by the Singapore National Research Foundation under its Competitive Research Program for the project entitled, "Advanced FO Membranes and Membrane Systems for Wastewater Treatment, Water Reuse and Seawater Desalination" (Grant Number: R-279-000-336-281) and was also supported by the Singapore National Research Foundation under its Environmental 81 Water Technologies Strategic Research Programme and administered by the Environment & Water Industry Programme Office (EWI) of the PUB under the project titled "Membrane Development for Osmotic Power Generation, Part 1. Materials Development and Membrane Fabrication" (1102-IRIS-11-01) and NUS Grant No. R-279-000-381-279. The authors would like to thank Mr. Wang Peng for his suggestions.en
dc.publisherElsevier BVen
dc.subjectHollow fiberen
dc.subjectOsmotic poweren
dc.subjectPolyethersulfoneen
dc.subjectPressure retarded osmosisen
dc.subjectThin film compositeen
dc.titleDesign of robust hollow fiber membranes with high power density for osmotic energy productionen
dc.typeArticleen
dc.contributor.departmentWater Desalination and Reuse Research Center (WDRC)en
dc.identifier.journalChemical Engineering Journalen
dc.contributor.institutionDepartment of Chemical and Biomolecular Engineering, National University of Singapore, Singapore 117576, Singaporeen
kaust.authorChung, Neal Tai-Shungen
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