Abstract
In separation of oil from oil–water emulsion by electrocoagulation in an electrolytic cell with a fixed-bed anode which is made of randomly packed aluminum cylinders in a perforated plastic basket, the cathode was a horizontal aluminum plate placed below the bed anode at the cell bottom. The effects of different variables such as current density, bed height, cylinder diameter, NaCl concentration on the rate of oil removal, and electrical energy consumption were studied. Under optimum conditions, the separation efficiency reached 85 % after 5 min and a maximum of 99 % after 35 min. The rate of oil removal and oil separation efficiency increased with increasing the current density and NaCl concentration. Increasing bed height was found to increase the rate of oil removal and separation efficiency. It was also found that there was an optimum (cylinder diameter) at which the rate of oil removal and separation efficiency were higher than those at other diameters. Electrical energy consumption, which ranged from 0.35 to 27.5 kW h/kg of oil removed, was found to increase with increasing the current density, bed height and decreasing NaCl concentration. Energy consumption was found to decrease at optimum cylinder diameter. For 99 % oil removal, Al consumption under the present range of conditions ranged from 0.017 to 0.34 g/L of emulsion and the amount of sludge ranged from 0.55 to 1.48 g/L depending on the operating conditions. Comparison of the performance of the present cell with traditional cells shows that the present cell is superior to traditional cells such as the vertical parallel plate cell.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- C 0 :
-
Initial oil concentration (ppm)
- C :
-
Oil concentration, at any time (%)
- c.d.:
-
Current density (A/cm2)
- E.E.C.:
-
Electrical energy consumption (K.W.h/kg of oil removed
- E :
-
Total cell voltage (V)
- E equ :
-
Equilibrium cell voltage (V)
- e cathode :
-
Cathodic potential (V)
- e anodic :
-
Anodic potential (V)
- I :
-
Cell current (A)
- IR:
-
Ohmic drop (V)
- m :
-
Amount of oil removed (kg/h)
- R :
-
Solution resistance (Ohm)
- η a :
-
Anodic polarization (V)
- η c :
-
Cathodic polarization (V)
- ρ :
-
Resistivity of the solution containing bubble (ohm cm)
- ρ 0 :
-
Resistivity of the solution containing without bubble (ohm cm)
- ∈:
-
Gas holdup
References
Al-Fetlawi, H., Shah, A. A., & Walsh, F. C. (2010). Modeling the effect of oxygen effect in all—vanadium redox flow battery. Electrochimica Acta, 55, 3192–3205.
Benito, J. M., Rios, G., Pazos, C., & Coca, J. (1998). Methods for the separation of emulsified oil from water. A state of the art review. Trends in Chemical Engineering, 4, 203–231.
Carmona, M., Khemis, M., Leclerc, J. P., & Lapicque, F. A. (2006). Simple model to predict the removal of oil suspensions from water using the electrocoagulation technique. Chemical Engineering Science, 61, 1237–1246.
Chen, G. (2004). Electrochemical technologies in waste water treatment. Separation and Purification Technology, 38, 11–41.
Chen, X., Chen, G., & Yue, P. L. (2000). Separation of pollutants from restaurant wastewater by electrocoagulation. Separation and Purification Technology, 19, 65–76.
Dimoglo, A., Akbult, H. Y., Ghan, F., & Karpuzou, M. (2004). Ptrochemical wastewater treatment by means of clean electrochemical technologies. Clean Technologies and Environmental Policy, 6, 288–295.
Donini, J. C., Kan, J., Szynkarczuk, J., Hassan, T. A., & Kar, K. L. (1994). The operating cost of the electrocoagulation. Canadian Journal of Chemical Engineering, 72, 1007–1012.
Emamjomeh, M. M., & Sivakumar, M. (2009). Review of pollutants removed by electrocoagulation and electrocoagulation/flotation process. Journal of Environmental Management, 90, 1663–1679.
Fouad, Y. O., Konsowa, A. H., Farag, H. A., & Sedahmed, G. H. (2009). Performance of an electrocoagulation cell with horizontally oriented electrodes in oil separation compared to a cell with vertical electrodes. Chemical Engineering Journal, 145, 436–440.
Gao, P., Chen, X., Shen, F., & Chen, G. (2005). Removal of chromium (VI) from wastewater by combined electrocoagulation-electroflotation without a filter. Separation and Purification Technology, 43, 117–123.
Holt, P. K., Barton, G. W., & Mitchell, C. A. (2005). The future for electrocoagulation as a localized water treatment technology. Chemosphere, 59, 335–367.
Juttner, K., Galla, U., & Schmieder, H. (2000). Electrochemical approaches to environmental problems in the process industry. Electrochimica Acta, 45, 2575–2594.
Kikuchi, k., Nagata, S., Tanaka, Y., Saihara, Y., & Ogumi, Z. (2007). Characteristics of hydrogen nanobubbles in solutions obtained with water electrolysis. Journal of Electroanalytical Chemistry, 600, 303–310.
Mallah, M. Y., Markovsky, P., Gomes, J. A., Kesmez, M., Parga, J., & Cocke, D. L. (2004). Fundamentals, present and future perspectives of electrocoagulation. Journal of Hazardous Materials, B114, 199–210.
Mechelhoff, M., Kelsall, G. H., & Graham, N. J. (2013). Electrochemical behavior of aluminum in electrocoagulation processes. Chemical Engineering Science, 95, 301–312.
Mostefa, N. M., & Tir, M. (2004). Coupling flocculation with electrofloation for waste oil/water emulsion treatment: optimization of the operating conditions. Desalination, 161, 115–121.
Mouedhen, G., Feki, M., De Petris Werg, M., & Ayedi, H. F. (2008). Behavior of aluminum electrodes in electrocoagulation process. Journal of Hazardous Materials, 150, 124–135.
Rajeshwar, K., Ibanez, J. B., & Swain, G. M. (1994). Electrochemistry and environmental. Journal of Applied Electrochemistry, 24, 1077–1091.
Rios, G., Pazos, C., & Coca, J. (1998). Destabilization of cutting oil emulsions using inorganic salts as coagulants, colloids and surface A. Physiochemical and Engineering Aspects, 138, 383–389.
Shah, A. A., Al-Fetlawi, H., & Walsh, F. C. (2010). Dynamic modeling of hydrogen evolution effect in the all—vanadium redox flow battery. Electrochimica Acta, 55, 1125–1139.
Sedahmed, G. H. (1987). Mass transfer at packed bed gas evolving electrodes. Journal of Applied Electrochemistry, 17, 746–752.
Sedahmed, G. H., & Shemilt, L. W. (1982). A mass transfer study of new electrochemical reactor stirred by gas evolved at counter electrode. Canadian Journal of Chemical Engineering, 60, 767–771.
Sedahmed, G. H. (1986). Electrochemical mass transfer at fixed bed of spheres under forced convection induced by counter electrode gas bubbles. Canadian Journal of Chemical Engineering, 64, 75–79.
Szpyrkowicz, L. (2005). Hyrodynamic effect on the performance of electrocoagulation/electrofloatation for the removal of dyes from textile wastewater. Industrial and Engineering Chemistry Research, 44, 7844–7853.
Vogt, H. (1983). Gas-evolving electrodes. Comprehensive Treatise of Electrochemistry, 6, 445–489.
Walsh, F. (1993). A first course in electrochemical engineering. The Electrochemical Consultancy, Hants (U.K).
Williams, R.A. (1994). Colloids and surface engineering—application in the process industries. Butterworth-Heinemann, London.
Zewail, T. M., Zatout, A. A., & Sedahmed, G. H. (2011). Study of the rate of diffusion controlled liquid–solid reactions accompanied with gas generation in batch fixed bed reactor in relation to waste water treatment. Chemical Engineering Journal, 172, 609–614.
Zuo, Q., Chen, X., Li, W., & Chen, G. (2008). Combined electrocoagulation and electroflotation for removal of fluoride from drink water. Journal of Hazardous Materials, 159, 452–457.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Hassan, I., Nirdosh, I. & Sedahmed, G.H. Separation of Oil from Oil–Water Emulsions by Electrocoagulation in an Electrochemical Reactor with a Fixed-Bed Anode. Water Air Soil Pollut 226, 271 (2015). https://doi.org/10.1007/s11270-015-2521-4
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s11270-015-2521-4