Application of Modified Maxwell-Stefan Equation for Separation of Aqueous Phenol by Pervaporation
Authors: Ujjal K Ghosh, Ling Teen
Abstract:
Pervaporation has the potential to be an alternative to the other traditional separation processes such as distillation, adsorption, reverse osmosis and extraction. This study investigates the separation of phenol from water using a polyurethane membrane by pervaporation by applying the modified Maxwell-Stephen model. The modified Maxwell-Stefan model takes into account the non-ideal multi-component solubility effect, nonideal diffusivity of all permeating components, concentration dependent density of the membrane and diffusion coupling to predict various fluxes. Four cases has been developed to investigate the process parameters effects on the flux and weight fraction of phenol in the permeate values namely feed concentration, membrane thickness, operating temperature and operating downstream pressure. The model could describe semi-quantitatively the performance of the pervaporation membrane for the given system as a very good agreement between the observed and theoretical fluxes was observed.
Keywords: Pervaporation, Phenol, Polyurethane, Modified Maxwell-Stefan equation, Solution Diffusion
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1335990
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[1] E. El-Zanati, E. Abdel-Hakim, O. El-Ardi and M. Fahmy, "Modeling and simulations of butanol separation aqueous solutions using pervaporation”, Journal of Membrane Science, vol. 280, pp.278-283, 2006.
[2] E. B. Moraes, M.E.T. Alvarez, F.R. Perioto and M.R. Wolf-Marciel n.d., "Modeling and simulation for pervaporative process: an alternative for removing phenol from wastewater”, http://www.aidic.it/icheap9/webpapers/285Moraes.pdf
[3] T. Gupta, N. C. Pradhan and B. Adhikari, "Separation of Phenol from Aqueous solution by pervaporation using HTPB based polyurethaneurea membrane”, Journal of Membrane Science, vol. 217, pp. 43-53, 2003.
[4] U. K. Ghosh, N. C. Pradhan and B. Adhikari, "Separation of Water and o-Chlorophenol by Pervaporation using HTPB-based Polyurethaneurea Membranes and Application of Modified Maxwell-Stefan Equation”, Journal of Membrane Science, vol. 272, pp. 93-102, 2006.
[5] H-J. Park and T-S. Chung, "Removal of Phenol from Aqueous Solution by Liquid Emulsion Membrane”, Korean Journal of Chemical Engineering, vol. 20, pp. 731-735, 2003.
[6] S. W. Park, C. F. Kaseger, J. K. Moon and J. H. Kim, "Mass transfer of phenol through supported liquid membrane”, Korean Journal of Chemical Engineering, vol. 13, pp. 596-605, 1996.
[7] U. K. Ghosh, N.C. Pradhan and B. Adhikari, "Pervaporative Recovery of N-Methyl-2-pyrrolidone from Dilute Aqueous Solution ”, Journal of Membrane Science, vol. 285, pp. 249-257, 2006.
[8] J. G. Wijimans and R. W. Baker, "The solution-diffusion model: a review”, Journal of Membrane Science vol. 107, pp. 1-21, 1995.
[9] P. Izak, L. Bartovska, K. Friess, M. Sipek, and P. Uchytil, "Description of binary liquid mixtures transport through non-porous membrane by modified Maxwell-Stefan equations", Journal of Membrane Science, vol. 214, pp. 293-309, 2003.
[10] E. A. Mason, and L. A. Viehland., Journal of Chemical Physics, vol., 68, pp. 3562, 1978.
[11] M. E. McComb, R. D. Oleschuk, D. M. Manley et al., ""Use of a Nonporous Polyurethane Membrane as a Sample Support for Matrix-assisted Laser Desorption/Ionisation Time-of-flight Mass Spectronomy of Peptides and Proteins”, Rapid Communications in Mass Spectronomy II, 1716-1722, 1997.
[12] A. Wolinska-Grabczyk, J. Muszynski, and A. Jankowski, "Applications of Polyurethane-Based Membranes in Pervaporation Separations”, Chem. Papers, vol. 54, pp. 389, 2000.
[13] M. Hoshi, M. Kogure, T. Saitoh and T. Nakagawa, "Separation of Aqueous Phenol through Polyurethane Membranes by Pervaporation." Journal of Applied Polymer Science, vol. 71, pp. 469, 1997.
[14] F. Pithan and C. Staudt-Bickel, "Crosslinked copolymide membranes for phenol recovery from process water by pervaporation”, Chemphyschem, vol. 4, pp. 967, 2003.
[15] M. Peng, L. M. Vane and S. X. Liu, "Recent advances in VOCs removal from water from pervaporation”, Journal of Hazardous Materials, vol. 98, pp. 69, 2003.