SciELO - Scientific Electronic Library Online

SciELO - Scientific Electronic Library Online

Referencias del artículo

PARENTIS, M.; BONINI, N.  y  GONZO, E. E.. Effectiveness factor calculation and monolith reactor simulation with non-uniform washcoat and arbitrary catalytic activity distribution. Lat. Am. appl. res. [online]. 2011, vol.41, n.1, pp. 57-62. ISSN 0327-0793.


    1. Au, S.A., J. Dranoff and J.B. Butt, "Nonuniform activity distribution in Catalyst Particles: Benzene Hydrogenation on Supported Nickel in a single Pellet Diffusion Reactor," Chem. Eng. Sci., 50, 3801-3812 (1995). [ Links ]


    2. Bischoff, K. and G. Froment, Chemical Reactor Analysis and Design, Wiley, New York (1980). [ Links ]


    3. Chauhan, S. and V.K. Srivastava, "Modeling Catalytic and Homogenous Combustion of Hydrocarbons in Monolithic Converters," Chemical Product and Process Modeling, 3, Article 10 (2008). [ Links ]


    4. Donsi, F., A. Di Benedetto, F.S. Marra and G. Russo, "Effect of the Re number on heat and mass transport in a catalytic monolith," Catalysis Today, 117, 498-505 (2006). [ Links ]


    5. Geus, J.W. and J.C. van Giezen, "Monoliths in catalytic oxidation," Catal. Today, 47, 169-180 (1999). [ Links ]


    6. Gonzo, E.E., "Hydrogen from methanol-steam reforming: Isothermal and adiabatic monolith reactors' simulation," Int. J. Hydrogen Energy, 33, 3511-3516 (2008). [ Links ]


    7. Gonzo, E.E. and J.C. Gottifredi, "Heat and mass transport limitations in monolith reactor simulation with non uniform washcoat thickness," Lat. Am. Appl. Res., 40, 15-21 (2010). [ Links ]


    8. Gottifredi, J.C., E.E.Gonzo and O.D. Quiroga, "Effectiveness Factor Calculation," in Chemical Reactor Concept and Design. (Whitaker and Cassano Eds.). Gordon and Breach Pub., New York (1986). [ Links ]


    9. Gupta, N. and V. Balakotaiah, "Heat and Mass taransfer coefficients in catalytic monoliths," Chem. Eng. Sci., 56, 4771-4786 (2001) [ Links ]


    10. Hayes, R.E., B. Liu, R. Moxom and M. Votsmeier, "The effect of washcoat geometry on mass transfer in monolith reactors," Chem. Eng. Sc., 59, 3169-3181 (2004). [ Links ]


    11. Hayes, R.E., B. Liu and M. Votsmeier, "Calculating effectiveness factors in non-uniform washcoat shapes," Chem. Eng. Sci., 60, 2037 - 2050 (2005). [ Links ]


    12. Heck, R.M. and R.J. Farrauto, "Automobile exhaust catalysts," Appl. Catalysis. A: Gen., 221, 443-457 (2001). [ Links ]


    13. Holmgren, A. and B. Andersson, "Mass transfer in Monolith catalyst - CO oxidation experiments and simulations," Chem. Eng. Sci., 53, 2285-2298 (1998). [ Links ]


    14. Irandoust, S., A. Cybulski and J.A. Moulijn, "The use of monolithic catalysts for three-phase reactions," in: Cybulski, A. Moulijn, J.A. (Eds). Structured Catalysts and Reactors. Marcel Dekker, New York, 239-265 (1998). [ Links ]


    15. Kim, D.H. and J.A. Lee, "A robust iterative method of computing effectiveness factors in porous catalysts," Chem. Eng. Sci., 59, 2253-2263 (2004). [ Links ]


    16. Kubicek, M. and E. Hlavacek, Numerical Solution of Nonlinear Boundary Value Problems with Applications, Prentice-Hall, Inc. Englewood Cliffs, N. J. (1983). [ Links ]


    17. Li, M.D., Y.W. Li, Z.F., Qin and S.Y., Chen, "Theoretical prediction and experimental validation of the Egg-Shell distribution of Ni for supported Ni/Al2O3 Catalysts," Chem. Eng. Sci., 49, 4889-4895 (1994). [ Links ]


    18. Machado, R.M., R.R. Broekhuis, A.F. Nordquist, B.P. Roy and R. Carney, "Applying monolith reactors for hydrogenations in the production of specialty chemicals-process and economic considerations," Catal. Today, 105, 305-317 (2005). [ Links ]


    19. Papadias, D., L. Edsberg and P. Björnbom, "Simplified method of effectiveness factor calculations for irregular geometries of washcoat. A general case in a 3D concentration field," Catal. Today, 60, 11-20 (2000). [ Links ]


    20. Sari, A., A. Safecordi and F.A. Farhadpour, "Comparison and validation of Plug and Boundary layer flow models of monolithic Reactors: Catalytic Partial Oxidation of Methane on Rh coated monoliths," International Journal of Reactor Engineering, 6, A73 (2008). [ Links ]


    21. Tischer, S. and O. Deutschmann, "Recent advances in Numerical Modeling of Catalytic Monolith Reactors," Catal. Today, 105, 407-413 (2005). [ Links ]


    22. Tomasic, V., S. Zrncevic and Z., Gomzi, "Direct decomposition of NO in a monolith reactor: comparison of mathematical models," Catal. Today, 90, 77-83 (2004). [ Links ]


    23. Tomasic, S. and Z. Gomzi, "Experimental and theoretical study of NO decomposition in a catalytic monolith reactor," Chem. Eng. and Proc., 43, 765-774 (2004). [ Links ]


    24. Valentini, M., G. Groppi, C. Cristiani, M. Levi, E. Tronconi and P., Forzatti, "The deposition of γ-Al2O3 layers on ceramic and metallic supports for the preparation of structured catalysts," Catal. Today, 69, 307-314 (2001). [ Links ]


    25. Villadsen, J. and M.L. Michelsen, Solution of Differential Equation Models by Polynomial Approximation, Prentice-Hall, Inc. Englewood Cliffs, N. J. (1978). [ Links ]


    26. Williams, J.L., "Monolith structures, materials, properties and uses," Catal. Today, 69, 3-9 (2001). [ Links ]