Czasopismo
2002
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Vol. 2, no. 2
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101--108
Tytuł artykułu
Autorzy
Wybrane pełne teksty z tego czasopisma
Warianty tytułu
Języki publikacji
Abstrakty
There has been increasing worldwide interest in the field of technical textile materials. Within this context the use of membranes for industrial separation processes has developed, and they can now compete effectively with conventional processes in terms of energy and capital costs. Membranes for gas separation have developed significantly in the last twenty years; however, there is still a need for high-temperature and chemically resistant membranes that exhibit good selectivity and gas permeability. In spite of the developments in gas separation membranes, only a few types of hollow-fibre membranes are still commercially available. Our study examines the fundamental properties of polyetherketone (PEK, a thermally stable and chemically resistant polymer) membranes prepared using concentrated sulphuric acid (98% H2SO4) as a solvent and dilute sulphuric acid (30%-60% H2SO4) as a non-solvent. Other non-solvents included acetic acid, ethanol, methanol, glycerol, and water. The concentration of the polymer-casting solutions was between 15% and 20%. The membrane structure was examined using SEM, and the gas separation properties were measured using a lab-scale test rig. The results show that formation and control of membrane structure are complicated, and that many preparation parameters affect membrane morphology and performance. Polymer concentration is a particularly important parameter. At each individual polymer concentration, the precipitant plays a crucial role, and has a determining influence on membrane structure. Membranes cast using 30-40% glycerol and 50-60% H2SO4 or 70-90% acetic acid as precipitants possessed sponge-type structures, and as such have an acceptable permeation rate. However, membranes cast into water display finger-like structures even at a low coagulation temperature of 3?C, and also exhibit lower permeation rates. It has also been shown that precipitated structures of PEK membranes are highly dependent upon the heat of mixing of the solvent with non-solvent, and that a reduction in this heat of mixing leads to sponge-like structures that are preferential for gas separation membranes.
Czasopismo
Rocznik
Tom
Strony
101--108
Opis fizyczny
Bibliogr. 13 poz.
Twórcy
autor
- School of Materials Science and Engineering, Clemson University South Carolina, USA 29634
autor
- School of Materials Science and Engineering, Clemson University South Carolina, USA 29634
autor
- Department of Textile Industries, University of Leeds, Leeds LS2 9JT, UK
Bibliografia
- 1. Kesting, R E & Fritzsche, A K: Polymeric Gas Separation Membranes, John Wiley & Sons, Inc., New York (1993)
- 2. Koros, W J & Fleming, G K: ‘Membrane-based gas separation’, J. Memb. Sci. Vol 83 (1993), pp 1-80
- 3. Matsuyama, H, Berghmans, S & Lloyd, D R: ‘Formation of anisotropic membranes via thermally induced phase separation’, Polymer, Vol 40 (1999), p 2289
- 4. Wang, D, Li, K & Teo, W K: ‘Phase separation in polyetherimide/solvent/non-solvent systems and membrane formation’, J. Appl. Polym. Sci. Vol 71 (1999), pp 1789-1796
- 5. Boom, R M, Rolevink, H W W, van den Boomgaard, T & Smolders, C A: ‘Microscopic structures in phase inversion membranes: the use of polymer blends for membrane formation by immersion precipitation’, Macromol. Symp. Vol 69 (1993), pp 133-140
- 6. Frommer, M A, Feiner, I, Kedem, D & Bloch, D: ‘The mechanism for formation of skinned membranes’, Desalination, vol 7 (1973), pp 393-405
- 7. Strathmann, H: ‘Production of microporous media by phase inversion processes’, in Lloyd, D R (Ed.), Materials Science of Synthetic Membranes, American Chemical Society, Washington D.C. (1985), pp 165-195
- 8. Strathmann, H: ‘Synthetic membranes and their preparation’, in Porter, M C (Ed), Handbook of Industrial Membrane Technology, Park Ridge, Noyes, (1990), pp 1-26
- 9. Strathmann, H, Scheible, P & Baker, R W: A rationale for the preparation of Loeb-Sourirajan-Type cellulose acetate membranes’, J. Appl. Polym. Sci. Vol 15 (1971) pp 811-828
- 10. Strathmann, H & Kock, K: ‘The formation mechanism of phase inversion membranes’, Desalination, Vol 21 (1977), pp 241-255
- 11. Brown, P J, Rogers-Gentile, V & Ying, S: ‘Polyetherketone hollow fiber membranes for gas separation’, Proc. 8th World Filtration Congress, Brighton, UK, (3-7 April 2000), pp 221-224
- 12. Ying, S, Rogers-Gentile, V & Brown, P J: ‘Preparation and characterization of polyetherketone hollow fiber membranes for gas separation’, J. Text. Inst. Vol 90 No 3 (1999), pp 30-41
- 13. Van Krevelen, D W: Properties of Polymers, Elsevier; Amsterdam, 3d ed, (1990), pp 774-789
Typ dokumentu
Bibliografia
Identyfikatory
Identyfikator YADDA
bwmeta1.element.baztech-3c8dcd3f-c441-4cbf-9c42-669c3e26543b