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The relation between structure-performance of thin film composite membranes and the tools used for their fabrication method

Lipnizki, Frank LU orcid ; Briceno, Kelly ; Javakhishvili, Irakli ; Guo, Haofei ; Christensen, Knud Villy ; Norddahl, Birgir and Hvilsed, Søren (2016) North American Membrane Society 26th Annual Meeting
Abstract
For more than 30 years polyimides (PA) have been one of the main polymers for the fabrication of thin film composite membranes. Several researchers have assessed the main fabrication variables that influence the final structure of the polyamide layers including monomer concentration, solvents, additives in aqueous and organic phases and type of support to mention few [1,2]. However, few studies have reported the influence of the fabrication tools used in the preparation of the PA layer. Each research group report their own recipe and fabrication method accordingly to the general criteria of avoiding bubble formation during fabrication as that would later compromise the function of the membrane, but each process step must be well... (More)
For more than 30 years polyimides (PA) have been one of the main polymers for the fabrication of thin film composite membranes. Several researchers have assessed the main fabrication variables that influence the final structure of the polyamide layers including monomer concentration, solvents, additives in aqueous and organic phases and type of support to mention few [1,2]. However, few studies have reported the influence of the fabrication tools used in the preparation of the PA layer. Each research group report their own recipe and fabrication method accordingly to the general criteria of avoiding bubble formation during fabrication as that would later compromise the function of the membrane, but each process step must be well controlled to obtain reliable and consistent membrane performance. In general, the fabrication of the polyamide membrane layer is carried out in two steps. A polymeric support is initially brought in contact with the aqueous phase containing metaphenylene diamine (MPD) monomer and then with the organic phase containing the trimesoly chloride (TMC) monomer in order to promote PA formation through interfacial polymerization. The critical step occurs immediately after the support has been in contact with the aqueous phase, because formation of irregular drops could be initiation points for defects during the second step process. Several tools has been used to eliminate the drop formation including air-knifes, rubber wipers, rubber rollers, glass rollers, or for that matter the absence of any tool using only water evaporation. In this work different methods of avoiding drop formation during the membrane preparation are tested to evaluate how the preparation methods influence the membrane structures and the final membrane properties. Understanding the membrane formation and consequently the defects formation will bring help to control and reproduce membrane preparation both in laboratory and industrial scale [3]. Specifically this work focuses on the preparation of a polyamide membrane layer supported by a polysulfone support after immersion in MPD/aqueous solution followed by immersion in TMC/heptane solution. The polysulfone support is in contact with the MPD/aqueous phase using immersion or pipetting. Further the use of a rubber wiper or absences of any tool to eliminate the aqueous solution droplets are evaluated. Both NaCl rejection and water & NaCl fluxes are evaluated, in order to relate them with the structural characteristics of the membranes using SEM, contact angle and streaming potential.

[1] Asim K. Ghosh, Byeong-Heon Jeong, Xiaofei Huang, Eric M.V. Hoek , Impacts of reaction and curing conditions on polyamide composite reverse osmosis membrane properties, Journal of Membrane Science 311 (2008) 34–45
[2] Liwei H, McCutcheon J, Impact of support layer pore size on performance of thin film composite membranes for forward osmosis, Journal of Membrane Science 483(2015)25–33
[3] R. Rangarajan, N.V. Desai, S.L. Daga, S.V. Joshi, A. Prakash Rao, V.J. Shah, J.J. Trivedi, C.V. Devmurari, K. Singh, P.S. Bapat, H.D. Raval, S.K. Jewrajka, N.K. Saha, A. Bhattacharya, P.S. Singh, Paramita Ray, G.S. Trivedi, N. Pathak, A.V.R. Reddy, Thin film composite reverse osmosis membrane development and scale up at CSMCRI, Bhavnagar, Desalination 282 (2011) 68–77 (Less)
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author
; ; ; ; ; and
organization
publishing date
type
Contribution to conference
publication status
published
subject
keywords
Reverse osmosis, Thin-film membrane
conference name
North American Membrane Society 26th Annual Meeting
conference location
Bellevue, United States
conference dates
2016-05-21 - 2016-05-25
external identifiers
  • scopus:85040320564
language
English
LU publication?
yes
id
45aae65f-a8bd-4bb4-8225-b8bdbbfef576
date added to LUP
2018-10-15 05:25:05
date last changed
2023-09-08 08:58:08
@misc{45aae65f-a8bd-4bb4-8225-b8bdbbfef576,
  abstract     = {{For more than 30 years polyimides (PA) have been one of the main polymers for the fabrication of thin film composite membranes. Several researchers have assessed the main fabrication variables that influence the final structure of the polyamide layers including monomer concentration, solvents, additives in aqueous and organic phases and type of support to mention few [1,2]. However, few studies have reported the influence of the fabrication tools used in the preparation of the PA layer.  Each research group report their own recipe and fabrication method accordingly to the general criteria of avoiding bubble formation during fabrication as that would later compromise the  function of the membrane, but each process step must be well controlled to obtain reliable and consistent membrane performance. In general, the fabrication of the polyamide membrane layer is carried out in two steps. A polymeric support is initially brought in contact with the aqueous phase containing metaphenylene diamine (MPD) monomer and then with the organic phase containing the trimesoly chloride (TMC) monomer in order to promote PA formation through interfacial polymerization. The critical step occurs immediately after the support has been in contact with the aqueous phase, because formation of irregular drops could be initiation points for defects during the second step process. Several tools has been used to eliminate the drop formation including air-knifes, rubber wipers, rubber rollers, glass rollers, or for that matter the absence of any tool using only water evaporation. In this work different methods of avoiding drop formation during the membrane preparation are tested to evaluate how the preparation methods influence the membrane structures and the final membrane properties. Understanding the membrane formation and consequently the defects formation will bring help to control and reproduce membrane preparation both in laboratory and industrial scale [3]. Specifically this work focuses on the preparation of a polyamide membrane layer supported by a polysulfone support after immersion in MPD/aqueous solution followed by immersion in TMC/heptane solution. The polysulfone support is in contact with the MPD/aqueous phase using immersion or pipetting. Further the use of a rubber wiper or absences of any tool to eliminate the aqueous solution droplets are evaluated.  Both NaCl rejection and water &amp; NaCl fluxes are evaluated, in order to relate them with the structural characteristics of the membranes using SEM, contact angle and streaming potential.<br>
<br>
[1] Asim K. Ghosh, Byeong-Heon Jeong, Xiaofei Huang, Eric M.V. Hoek , Impacts of reaction and curing conditions on polyamide composite reverse osmosis membrane properties, Journal of Membrane Science 311 (2008) 34–45<br>
[2] Liwei H, McCutcheon J, Impact of support layer pore size on performance of thin film composite membranes for forward osmosis, Journal of Membrane Science 483(2015)25–33<br>
[3] R. Rangarajan, N.V. Desai, S.L. Daga, S.V. Joshi, A. Prakash Rao, V.J. Shah, J.J. Trivedi, C.V. Devmurari, K. Singh, P.S. Bapat, H.D. Raval, S.K. Jewrajka, N.K. Saha, A. Bhattacharya, P.S. Singh, Paramita Ray, G.S. Trivedi, N. Pathak, A.V.R. Reddy, Thin film composite reverse osmosis membrane development and scale up at CSMCRI, Bhavnagar,  Desalination 282 (2011) 68–77}},
  author       = {{Lipnizki, Frank and Briceno, Kelly and Javakhishvili, Irakli and Guo, Haofei and Christensen, Knud Villy and Norddahl, Birgir and Hvilsed, Søren}},
  keywords     = {{Reverse osmosis; Thin-film membrane}},
  language     = {{eng}},
  title        = {{The relation between structure-performance of thin film composite membranes and the tools used for their fabrication method}},
  year         = {{2016}},
}