Extraction of Lignosulfonate using TOA-Kerosene-PVDF in Supported Liquid Membrane Process
DOI:
https://doi.org/10.11113/jt.v67.2737Keywords:
Supported liquid membrane (SLM), lignosulfonate, extraction, tricotylamine (TOA), keroseneAbstract
Lignosulfonate is a major byproduct from the sulphite pulping process which is the most abundant biopolymer and largely unused. Although lignosulfonate is nontoxic, it impacts brownish black colour to water and makes the water unsuitable for reuse. However, lignosulfonate have a wide range application, such as production of vanillin, animal feed pellets binder and pesticides. Therefore, an efficient separation technique of lignosulfonate from the wastewater is necessary in order to meet the wastewater treatment requirement and as a source of valuable material for industrial applications. In this study, lignosulfonate was extracted from aqueous solution through flat sheet supported liquid membrane (SLM) using trioctylamine (TOA) as carrier. SLM has great potential for the separation lignosulfonate as it offers advantages such as simultaneous extraction and stripping steps, low consumption of carrier and high selectivity. The important parameters governing the extraction process are the types of support material, types of solvents, types of stripping agent, feed phase flow rate and pH were investigated. The favorable condition for extraction was obtained by using TOA-Kerosene-PVDF membrane system, 0.5M NaOH as stripping agent, 100 mL/min of flow rate and feed at pH 2 with 37.5% of lignosulfonate removal. The result demonstrated that the membrane support remains stable for more than 9 hours, hence demonstrating promising separation technique for lignosulfonate.
References
Holladay, J.E., J.J. Bozell, J.F. White, and D. Johnson. 2007. Top Value-Added Chemicals from Biomass Volume II: Results of Screening for Potential Candidates from Biorefinery Lignin. Technical Report. United States: Department of Energy (DOE).
Chakarbarty, K., P. Saha, and A.K. Ghoshal. 2009. Separation of Lignosulfonate from Its Aqueous Solution Using Supported Liquid Membrane. Journal of Membrane Science. 340(1–2): 84–91.
Kroschwitz, J. I., and A. Seidel. 2005. Lignin In Kirk-OthmerEncyclopedia of Chemical Technology. 5thEd. Hoboken, N.J. Wiley-Interscience. 15: 1–25.
Liu, G., Y. Liu, J. Ni, H. Shi, and Y. Qian. 2004. Treatability of Kraft Spent Liquor by Microfiltration and Ultrafiltration. Desalination. 160: 131–141.
Kocherginsky, N. M., Q. Yang, and L. Seelam. 2007. Recent Advances in Supported Liquid Membrane Technology. Separation and Purification Technology. 53: 171–177.
Canet, L. and P. Seta. 2001. Extraction and Separation of Metal Cations in Solution by Supported Liquid Membrane Using Iasalocid A as Carrier. Pure and Applied Chemistry. 73: 2039–2046.
Kamiński, W. and W. Kwapiński. 2000. Applicability of Liquid Membrane in Environmental Protection. Polish Journal of Environmental Studies. 9: 37–43.
Kontturi, A.K., K. Kontturi, P. Niinikoski, and G. Sundholm. 1990. Extraction of a Polyelectrolyte Using a Supported Liquid Membrane, I. Choice of a Suitable Carrier-Solvent System.Acta Chemica Scandinavica 44: 879–882.
Kontturi, A. K., K. Kontturi, P. Niinikoski, and G. Sundholm. 1990. Extraction of a Polyelectrolyte Using a Supported Liquid Membrane, II. Extraction and Fractionation of Lignosulfonate. Acta Chemica Scandinavica. 44: 883–891.
Dżygiel, P., and P.P. Wieczorek. 2010. Supported Liquid Membranes and Their Modifications: Definition, Classifications, Theory, Stability, Application and Perspectives. In Kislik, V. S. (Ed.). Liquid Membranes Principles and Applications in Chemical Separations and Wastewater Treatment.73–140.
Chakrabarty, K., K. V. Krishna, P. Saha, and A. K. Ghoshal. 2009. Extraction and Recovery of Lignosulfonate from Its Aqueous Solution Using Bulk Liquid Membrane. Journal of Membrane Science. 220: 135–144.
Altin, S., S. Alemdar, A. Altin, and Y. Yildirim. 2011. Facilitated Transport of Cd(II) Through a Supported Liquid Membrane with Aliquat 336 as a Carrier. Separation Science and Technology. 46: 754–764.
Zheng, H. D., B.Y. Wang, Y.X. Wu, and Q. L. Ren. 2009. Instability Mechanisms of Supported Liquid Membranes for Copper (II) Ion Extraction. Colloid and Surfaces A. 351: 38–45.
Van de Voorde, I., L. Pinoy, and R.F. De Ketelaere. 2004. Recovery of nickel Ions by Supporting liquid Membrane (SLM) Extraction. Journal of Membrane Science. 234: 11–21.
Downloads
Published
Issue
Section
License
Copyright of articles that appear in Jurnal Teknologi belongs exclusively to Penerbit Universiti Teknologi Malaysia (Penerbit UTM Press). This copyright covers the rights to reproduce the article, including reprints, electronic reproductions, or any other reproductions of similar nature.
