ESTIMATION OF THE OPTIMUM BED THICKNESS OF A FLOWTHROUGH POROUS ELECTRODE (FTPE) WORKING UNDER MASS TRANSFER CONTROL

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Qasim J. M. Slaiman
Sarmad Talib Najim
Aws Abdulmahdi Sadeq

Abstract

In this paper, a theoretical analysis of optimum bed thickness operates under mass transfer control for realizing a high efficiency and reaction conversion of an electrochemical reactor has been made based on flowthrough porous electrode (FTPE) configuration. Many models have been used to represent the optimum bed thickness by taking a look into previous works concerned and collecting all related information, data, and models. The parameters that affect the optimum bed thickness have been visualized and reviewed, and almost all of them have been examined by experimental data from different sources and based on the various models. It has been found that the increase in electrolyte flow rate, concentration, limiting current density, and specific surface area reduce the optimum bed thickness, and the increase in electrolyte conductivity, void fraction, and overpotential range increases optimum bed thickness. The most important design parameter that has a great effect on optimum bed thickness is found to be the electrolyte flow rate for any certain operation. It has been concluded that the most appropriate two models to represent the optimum bed thickness of FTPE electrochemical reactor operating under mass transfer control based on the results are those predicted theoretically and stated by Kreysa in (1978) and Doherty et al. in (1996). 

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“ESTIMATION OF THE OPTIMUM BED THICKNESS OF A FLOWTHROUGH POROUS ELECTRODE (FTPE) WORKING UNDER MASS TRANSFER CONTROL” (2012) Journal of Engineering, 18(04), pp. 485–498. doi:10.31026/j.eng.2012.04.09.

References

Bennion, D. N., Newman, J., “Electrochemical removal of copper ions from very dilute solutions” J. Appl. Electrochem. 2, 133,(1972).

Coeuret, F., Hutin, D., Gaunand, A., “Study of the effectiveness of fixed flow-through electrodes” J. Appl. Electrochem. 6, 417(1976).

Doherty, T., Sunderland, J.G., Roberts,E.P.L., Pickett, D.J., “An improved model of potential and current distribution within a flow-through porous electrode” Electrochim. Acta. 41 (4), 519 (1996).

El-Deab, M. S., Saleh, M. M., El-Anadouli, B., E., Ateya, B. G., “Electrochemical removal of lead ions from flowing electrolytes using packed bed electrodes” J. Electrochem.Soc. 146 (1), 208 (1999).

Gaunand, A Hutin, D. and Coeuret, F., “Potential distribution in flow-through porous electrodes under limiting current” Electrochim. Acta. 22, 93 (1977).

Kreysa, G., “Kinetic behavior of packed bed and fluidized bed electrodes” Electrochim. Acta. 23, 1351 (1978).

Kreysa, G., Reynvaan, C., “Optimal design of packed bed cells for high conversion” J.Appl. Electrochem. 12, 241 (1982).

Kreysa. G., Jüttner, K., “Cylindrical threedimensional electrodes under limiting current conditions” J. Appl. Electrochem. 23,707 (1993).

Lanza, M.R.V., Bertazzoli, R., “Removal of Zn(II) from chloride medium using a porous electrode: current penetration within the cathode” J. Appl. Electrochem. 30, 61 (2000).

Masliy, A.I., Poddubny, N.P., “influence of solid phase conductivity on spatial localization of electrochemical processes in flowthrough porous electrodes” J. Appl. Electrochem. 27 (9) 1036 (1997).

Masliy, A. I., Poddubny, N. P., Medvedev,A. Zh., Zherebilov, A. F., “Modeling of the dynamics of metal deposition inside a flowthrough porous electrode with low initial conductivity” J. Electroanalytical Chemistry

Matloz, M.J., Newman, J., “Experimental investigation of a porous carbon electrode for the removal of mercury from contaminated brine” J .Electrochem. Soc. 133 (9),1850 (1986).

Najim, S. T., Kashmoula, T. B., Slaiman, Q.J. “Laboratory scale production of paminophenol using electrochemical reactor”Ph.D. thesis, Nahrain University (2006).

Nava, J.L., Oropeza, M.T., Ponce de León,C., González-García, J., Frías-Ferrer, A. J.,“Determination of the effective thickness of a porous electrode in a flow-through reactor;effect of the specific surface area of stainless steel fibres, used as a porous cathode, during the deposition of Ag(I) ions” Hydrometallurgy. 91, 98 (2008).

Newman, J., Tiedemann, W., “Porouselectrode theory with battery applications”AICHE Journal. 21 (1), 25 (1975).

Newman, J., Risch, T., “A theoretical comparison of flow-through and flow-by porous electrode at the limiting current” J. Electrochem. Soc. 131 (11), 2551 (1984).

Paulin, M., Hutin, D., Coeuret, F., “Theoretical and experimental study of flow-through porous elecrtrodes” J. Electrochem. Soc. 124 (2), 180 (1977).

Podlaha, E.J., Fenton, J.M., “Characterization of a flow-by RVC electrode reactor for the removal of heavy metals from dilute solutions”. J. Appl. Electrochem. 25, 299 (1995).

Ponce de León, C., Pletcher, D., “The removal of Pb(II) from aqueous solutions using a reticulated vitreous carbon cathode cell—the influence of the electrolyte medium”. Electrochim. Acta 41 (4), 533 (1996).

Sabacky, B.J., Evans, J.W., “Eectrodeposition of metals in fluidized bed electrodes Part I. Mathematical model”. J. Electrochem. Soc. 126, 1176 (1979).

Sadeq A. A., Najim, S. T., Slaiman, Q. J.“Theoretical analysis of the optimum bed thickness of an electrochemical reactor” M.Sc. thesis, Nahrain University (2009)

Saleh, M.M., “On the effectiveness factor of flow-through porous electrodes” J. Phys. Chem., B 108, 13419 (2004).

Soltan, E.A., Nosier, S.A., Salem, A.Y., Mansour, I.A.S., Sedahmed, G.H., “Mass transfer behaviour of a flow-by fixed bed electrochemical reactor under different hydrodynamic conditions”. Chem. Eng. J. 91,33 (2003).

Sioda R. E., “Distribution of potential in a pore electrode under conditions of flow electrolysis” Electrochim. Acta. 16, 1569 (1971).

Trainham, J. A. and Newman, J., “A flowthrough porous electrode model: Application to metal-ion removal from dilute streams” J. Electrochem. Soc. 124 (10), 1528 (1977).

Wilson, E. J., Geankoplis, C. J., Ind. Eng.Chem. Fund. 5, (1966).

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