High-temperature reverse osmosis and molecular separation with robust polyamide-ceramic membranes
High-temperature reverse osmosis and molecular separation with robust polyamide-ceramic membranes
Polyamide thin-film composite (TFC) membranes are widely used for reverse osmosis (RO), but most commercial RO membranes have a limited operating temperature of <45 °C. This has constrained the broader applications of RO in industries, where process and water feeds with high temperature >50 °C are common. In this study, robust polyamide-ceramic TFC membranes were developed for high-temperature RO (HT-RO). RO-type polyamide thin-film was successfully synthesized on the inner surface of ceramic tubular membranes via interfacial polymerization. The polyamide-ceramic membranes exhibited excellent thermal stability, maintaining high NaCl rejection (>98 %) and steady water permeability (∼5 LMH/bar) during HT-RO at 70 °C. The molecular weight cut-off (MWCO) of the membranes increased slightly from 90 to 140 Da at 70 °C, and the surface charge played an important role in maintaining the high salt rejection. Long-term stability tests showed that polyamide thin-films may undergo thermal hydrolysis at 80 °C. It was also found that polymeric substrates of flat-sheet RO membranes may experience serious compaction at high temperature, which could subsequently affect the performance and stability of the polyamide layer. The ceramic substrates provide strong support at high temperature, and the highly stable polyamide-ceramic membranes demonstrated huge potential for RO applications under more challenging conditions.
Ceramic composite membranes, High-temperature reverse osmosis (HT-RO), Interfacial polymerization, Polyamide thin-film
Chong, Jeng Yi
2f9ead94-86f2-4e20-9e67-75f10759555b
Zhao, Yali
859c8dc6-7752-4ceb-b783-8a95670ae88b
Wang, Rong
ecdc65c5-a659-4d0f-9d2e-3c978100d6dd
26 June 2024
Chong, Jeng Yi
2f9ead94-86f2-4e20-9e67-75f10759555b
Zhao, Yali
859c8dc6-7752-4ceb-b783-8a95670ae88b
Wang, Rong
ecdc65c5-a659-4d0f-9d2e-3c978100d6dd
Chong, Jeng Yi, Zhao, Yali and Wang, Rong
(2024)
High-temperature reverse osmosis and molecular separation with robust polyamide-ceramic membranes.
Chemical Engineering Journal, 495, [153277].
(doi:10.1016/j.cej.2024.153277).
Abstract
Polyamide thin-film composite (TFC) membranes are widely used for reverse osmosis (RO), but most commercial RO membranes have a limited operating temperature of <45 °C. This has constrained the broader applications of RO in industries, where process and water feeds with high temperature >50 °C are common. In this study, robust polyamide-ceramic TFC membranes were developed for high-temperature RO (HT-RO). RO-type polyamide thin-film was successfully synthesized on the inner surface of ceramic tubular membranes via interfacial polymerization. The polyamide-ceramic membranes exhibited excellent thermal stability, maintaining high NaCl rejection (>98 %) and steady water permeability (∼5 LMH/bar) during HT-RO at 70 °C. The molecular weight cut-off (MWCO) of the membranes increased slightly from 90 to 140 Da at 70 °C, and the surface charge played an important role in maintaining the high salt rejection. Long-term stability tests showed that polyamide thin-films may undergo thermal hydrolysis at 80 °C. It was also found that polymeric substrates of flat-sheet RO membranes may experience serious compaction at high temperature, which could subsequently affect the performance and stability of the polyamide layer. The ceramic substrates provide strong support at high temperature, and the highly stable polyamide-ceramic membranes demonstrated huge potential for RO applications under more challenging conditions.
Text
HT-RO_Accepted manuscript
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Accepted/In Press date: 17 May 2024
e-pub ahead of print date: 18 June 2024
Published date: 26 June 2024
Keywords:
Ceramic composite membranes, High-temperature reverse osmosis (HT-RO), Interfacial polymerization, Polyamide thin-film
Identifiers
Local EPrints ID: 492805
URI: http://eprints.soton.ac.uk/id/eprint/492805
ISSN: 1385-8947
PURE UUID: 162df7cb-8ece-458d-9895-d6fde75515ae
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Date deposited: 14 Aug 2024 16:53
Last modified: 15 Aug 2024 02:23
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Contributors
Author:
Jeng Yi Chong
Author:
Yali Zhao
Author:
Rong Wang
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