Abstract
The main aim of this work is to study the effect of scaling in the biosorption of chromium(VI) onto olive stone in two different fixed-bed columns. Firstly, the effect of flow rate, bed depth and inlet concentration of Cr(VI) in both columns was analyzed. The results revealed a better operation for lower flow rates, higher bed heights and lower inlet concentrations of metal. When decreasing flow rate, the operation time of the column increases. Therefore, as the solution flow rate increased the breakthrough and the exhaustion times decreased. An increase in bed depth increases the quantity of chromium eliminated and thus, the higher sorption capacity of the system. A decrease in the inlet concentration of chromium produces a delay in exhaustion time, and larger volumes of solution could be treated. The results were fitted to the BDST model, obtaining that the adsorptive capacity of the bed depth is similar in laboratory- and pilot-scale fixed-bed columns, considering the biosorption capacity as a biosorption-coupled reduction process. Results also could indicate that scaling affects more to the reduction process than properly biosorption process. The experimental data were also fitted to Adams–Bohart, Thomas, Yoon–Nelson and dose–response models. A good fit of the biosorption process of Cr(VI) was found for dose–response and Adams–Bohart models.
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References
Aksu Z, Gönen F (2004) Biosorption of phenol by immobilized activated sludge in a continuous packed bed: prediction of breakthrough curves. Process Biochem 39:599–613
Amirnia S, Ray MD, Margaritis A (2015) Heavy metals removal from aqueous solutions using Saccharomyces cerevisiae in a novel continuous bioreactor–biosorption system. Chem Eng J 264:863–872
Blázquez G, Hernáinz F, Calero M, Martín-Lara MA, Tenorio G (2009) The effect of pH on the biosorption of Cr(III) and Cr(VI) with olive stone. Chem Eng J 148:473–479
Bohart GS, Adams EQ (1920) Some aspects of the behaviour of the charcoal with respect chlorine. J Am Chem Soc 42:523–544
Bulgariu D, Bulgariu L (2013) Sorption of Pb(II) onto a mixture of algae waste biomass and anion exchanger resin in a packed-bed column. Bioresour Technol 129:374–380
Calero M, Hernáinz F, Blázquez G, Tenorio G, Martín-Lara MA (2009) Study of Cr(III) biosorption in a fixed-bed column. J Hazard Mater 171:886–893
Cruz-Olivares J, Pérez-Alonso C, Barrera-Díaz C, Ureña-Núñez F, Chaparro-Mercado MC, Bilyeu B (2013) Modeling of lead (II) biosorption by off all spice in a fixed-bed column. Chem Eng J 228:21–27
Eliche-Quesada D, Felipe-Sesé MA, Infantes-Molina A (2016) Olive stone ash as secondary raw material for fired clay bricks. Adv Mater Sci Eng. doi:10.1155/2016/8219437
Farooq U, Athar M, Khan MA, Kozinski JA (2013) Biosorption of Pb(II) and Cr(III) from aqueous solutions: breakthrough curves and modeling studies. Environ Monit Assess 185:845–854
Hutchins RA (1973) New method simplifies design of activated-carbon systems. Chem Eng 80:133–138
Inglezakis VJ, Poulopoulous SG (2006) Adsorption, ion exchange and catalysis. Design of operations and environmental applications. Elsevier, Amsterdam
Jain M, Garg VK, Kadirvelu K (2013) Cadmium(II) sorption and desorption in a fixed bed column using sunflower waste carbon calcium–alginate beads. Bioresour Technol 129:242–248
Ko DCK, Porter JF, McKay G (2000) Optimised correlations for the fixed-bed adsorption of metal ions on bone char. Chem Eng Sci 55:5819–5829
Martin-Lara M, Blázquez G, Trujillo MC, Pérez A, Calero M (2014) New treatment of real electroplating wastewater containing heavy metal ions by adsorption onto olive stone. J Clean Prod 81:120–129
Martín-Lara MA, Hernáinz F, Calero M, Blázquez G, Tenorio G (2009) Surface chemistry evaluation of some solid wastes from olive-oil industry used for lead removal from aqueous solutions. Biochem Eng J 44:151–159
Martín-Lara MA, Hernáinz F, Blázquez G, Tenorio G, Calero M (2010) Sorption of Cr(VI) onto olive stone in a packed bed column: prediction of kinetic parameters and breakthrough curves. J Environ Eng ASCE 136:1389–1397
Martín-Lara MA, Blázquez G, Ronda A, Pérez A, Calero M (2013) Development and characterization of biosorbents to remove heavy metals from aqueous solutions by chemical treatment of olive stone. Ind Eng Chem Res 52:10809–10819
Martín-Lara MA, Calero M, Ronda A, Pérez A, Trujillo MC (2016) Assessment of the removal mechanism of hexavalent chromium from aqueous solutions by olive stone. Water Sci Technol 73:2680–2688
Michalak I, Chojnacka K, Witek-Krowiak A (2013) State of the art for the biosorption process: a review. Appl Biochem Biotechnol 170:1389–1416
Mishra V, Balomajumder C, Agarwal VK (2013) Adsorption of Cu(II) on the surface of nonconventional biomass: a study on forced convective mass transfer in packed bed column. J Waste Manage 2013:1–8
Molokwane PE, Chirwa MN (2009) Cr(VI) reduction in packed-column microcosm reactors using chromium reducing microorganisms. Chem Eng Trans 18:863–868
Park D, Yun YS, Lee DS, Park JM (2011) Optimum condition for the removal of Cr(VI) or total Cr using dried leaves of Pinus densiflora. Desalination 271:309–314
Rojas G, Silva J, Flores JA, Rodriguez A, Ly M, Maldonado H (2005) Adsorption of chromium onto cross-linked chitosan. Sep Purif Technol 44:31–36
Ronda A, Martín-Lara MA, Almendros AI, Pérez A, Blázquez G (2015) Comparison of two models for the biosorption of Pb(II) using untreated and chemically treated olive stone: Experimental design methodology and adaptive neural fuzzy inference system (ANFIS). J Taiwan Inst Chem E 54:45–56
Rudolf E, Cervinka M (2005) The role of biomembranes in chromium(III)-induced toxicity in vitro. ATLA 33:249–259
Senthilkumar R, Vijayaraghavan K, Thilakavathi M, Iyer PVR, Velan M (2006) Seaweeds for the remediation of wastewaters contaminated with zinc(II) ions. J Hazard Mater 136:791–799
Shen YS, Wang SL, Huang ST, Tzou YM, Huang JH (2010) Biosorption of Cr(VI) by coconut coir: spectroscopic investigation on the reaction mechanism of Cr(VI) with lignocellulosic material. J Hazard Mater 179:160–165
Vijayaraghavan K, Balasubramanian R (2015) Is biosorption suitable for decontamination of metal-bearing wastewaters? A critical review on the state-of-the-art of biosorption processes and future directions. J Environ Manage 160:283–296
Vijayaraghavan K, Prabu D (2006) Potential of Sargassum wightii biomass for copper(II) removal from aqueous solutions: application of different mathematical models to batch and continuous biosorption data. J Hazard Mater 137:558–564
Xu Z, Cai JG, Pan BC (2013) Mathematically modeling fixed-bed adsorption in aqueous systems. J Zheijang Univ Sci A 14:155–176
Yoon YH, Nelson JH (1984) Application of gas adsorption kinetics I. A theoretical model for respirator cartridge service life. Am Ind Hyg Assoc J 45:509–516
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The authors are grateful to the Spanish Ministry of Science and Innovation for financial support received (Project CTM2009-10294).
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Martín-Lara, M.Á., Trujillo Miranda, M.C., Ronda Gálvez, A. et al. Valorization of olive stone as adsorbent of chromium(VI): comparison between laboratory- and pilot-scale fixed-bed columns. Int. J. Environ. Sci. Technol. 14, 2661–2674 (2017). https://doi.org/10.1007/s13762-017-1345-8
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DOI: https://doi.org/10.1007/s13762-017-1345-8