Title :
Global approximation of unsteady-state diffusion and reaction in slab, cylinder and sphere atalysts
Author_Institution :
Dept. of Chem. Eng., Kyungpook Nat. Univ., Taegu, South Korea
Abstract :
For unsteady-state diffusion, adsorption and a first-order reaction in a slab, cylinder and sphere catalyst, high-order approximations in the form of coupled ordinary differential equations are developed to substitute the exact partial differential equations. An infinite continued fraction is developed, which unifies the exact transfer functions of the three geometries as a function of the shape factor and the Thiele modulus in the Laplace domain. The time-domain approximations are obtained from the truncated continued fractions. The coefficients in the time-domain approximations are very easy to determine, and increasing the order of approximation is simple and straightforward.
Keywords :
Laplace equations; adsorption; catalysis; diffusion; reaction kinetics theory; slabs; transfer function matrices; Laplace domain; Thiele modulus; adsorption; coupled ordinary differential equations; cylinder catalysts; exact partial differential equations; exact transfer functions; first-order reaction; global approximation; high-order approximations; slab catalysts; sphere catalysts; time-domain approximations; unsteady-state diffusion; Approximation methods; Computational modeling; DH-HEMTs; Equations; Mathematical model; Slabs; Adsorption; Catalyst; Diffusion; Pore Diffusion Model; Reaction;
Conference_Titel :
Control, Automation and Systems (ICCAS), 2012 12th International Conference on
Conference_Location :
JeJu Island
Print_ISBN :
978-1-4673-2247-8
