Auszug
Wie schon bei der Diskussion der Triebkraft angeklungen ist (Kap. 1), kann die Leistung der Membranverfahren unter Umständen erheblich überschätzt werden, wenn nur der Stofftransport in der aktiven Membranschicht in Betracht gezogen wird.
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Literatur
Bird RB, Stewart WE, Lightfoot EN (1960) Transport Phenomena. John Wiley & Sons, New York
Brotz W (1954) Über die Vorausberechnung der Absorptionsgeschwindigkeit von Gasen in strömenden Flüssigkeiten. Chem Eng Technol 26: 470
Cabbasud C, Labrorie S, Durand-Bourlier L, Laine J M (2001) Air sparging in ultrafiltration hollow fibers: relationship between flux enhancement, cake characteristics and hydrodynamic parameters. J Membr Sc 181: 57–69
Chang S, Fane AG (2000) Filtration of biomass with axial inter-fiber upward slug flow: performance and mechanisms. J Membrane Sc 180: 57–68
Da Costa AR, Fane AG, Wiley DE (1994) Spacer characterization and pressure drop modelling in spacer-filled channels for ultrafiltration. J Membr Sc 87: 79–98
Dytnerski YI (1984) Concentration Polarization in Membrane Separations. Department of Chemical Engineering, Mendeleer Institute of Chemical Technology, 9 Musskaya sg., Moscow A-47
Fernandez RC, Semiat R, Dukler AE (1983) Hydrodynamic model for gas-liquid slug flow in vertical tubes, AIChE J 29(6): 981–989
Fuller EN, Shettler PD, Giddings JC (1966) Ind Eng Chem 58: 18
Gruber R (2001) Radial Mass Transfer Enhancement in Bubble-Train Flow. Dissertation, RWTH Aachen
Isaacson MS, Sonin AA (1976) Sherwood Number and Friction Factor Correlations for Electrodialysis Systems with Application to Process Optimization. Ind Eng Chem Process Des Develop 15(2)
Kay JM, Nedderman RM (1985) Fluid Mechanics and Transfer Processes: Chapter 19 Two phase flow. Cambridge University Press
Kimura S, Sourirajan S (1968) Concentration Polarization Effects in Reverse Osmosis Using Porous Cellulose Acetate Membranes. Ind Eng Chem Process Des Develop 7(1):42
Klatt S (1993) Zum Einsatz der Pervaporation im Umfeld der chemischen Industrie. Dissertation, RWTH Aachen
Klinkhammer B, Melin T (2000) Inorganic Membrane Module Design: Modelling of Fluid Dymnamics. Proceedings of ICIM-6, Montpellier
Kortenbusch M (1990) Zum Stofftransport bei der deckschichtbildenden Querstromfiltration kolloidaler Suspensionen. Dissertation, RWTH Aachen
Levenspiel O (1999) Chemical Reaction Engineering, 3 Auflage
Linton WH, Sherwood TK (1950) Chem Eng Progr 46: 258
Mulder M (1998) Basic Principles of Membrane Technology, 2nd edn Dordrechts
Psaume R, Aptel P, Aurelle Y, Mora YC, Bersillion JL (1988) Pervaporation: Importance of Concentration Polarization in the Extraction of Trace Organics from Water. J Membr Sc 36: 373
Rautenbach R, Albrecht R (1980) Separation of Organic Binary Mixtures by Pervaporation. J Membr Sci 7:203–223
Schlichting H (1982) Grenzschicht-Theorie. 8. Auflage, Friedrich Riegels, Karlsruhe
Schock G, Miguel A (1987) Mass Transfer and Pressure Loss in Spiral Wound Modules. Desalination 64: 339–352
Sherwood TK, Pigford RL, Wilke CR (1975) Mass Transfer. McGraw-Hill Chemical Engineering Series
Sieder EN, Tate GE (1936) Heat Transfer and Pressure Drop of Liquids in Tubes. Ind Eng Chem 28: 1429
Sommer S, Klinkhammer B, Melin T (2002) Integrated System Design for Dewatering of Solvents with Microporous Silica Membranes. Desalination 149:15–21
Struck A (1998) Untersuchung und Optimierung von Hohlfasermodulen für die Stickstoffanreicherung durch Gaspermeation. Dissertation, RWTH Aachen
Taha T, Cui Z F (2001) CFD modelling of gas-sparged ultrafiltration in tubular membranes. J Membr Sc 210: 13–27
Welsch K (1992) Gaspermeation-Membranwerkstoffe, Stofftransport und Anwendungsbeispiele. Dissertation, RWTH Aachen
Wilcox DC (1993) Turbulence Modeling for CFD. DCW Industries Inc. La Canada, California
Wilke C R, Chang P (1955) AIChE J 1: 264
Winograd A, Solan M, Toreau (1975) Mass Transfer in Narrow Chanels in the Presence of Turbulence Promoters. Desalination 13: 171
Wintgens T (2005) Modellierung von Membranbioreaktoren für die Abwasserbehandlung unter Berücksichtigung endokrin wirksamer Substanzen. Dissertation, RWTH Aachen
VDI-Wärmeatlas (2000) 8. Auflage, Abschnitt G, VDI-Verlag, Düsseldorf
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(2007). Stoffaustausch an Membranen. In: Membranverfahren. VDI-Buch. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-540-34328-8_4
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