On the axial dispersion approximation for laminar flow reactors

The continuous limit of a general random walk gives rise to the stochastic or Kolmogorov diffusion form of an axial dispersion model for tubular flow reactors. The resultant eauation is different from the Kolmogorov diffusion equations available in the literature, in that it includes a berm to accou

Axial dispersion or backmixing appears to be responsible for adverse mass velocity effects observed in trickle-flow laboratory reactors. At low Reynolds numbers typical of bench-scale units, the dispersion problem can be at least an order-of-magnitude more severe in trickle-flow than vaporphase oper

Approximate collocation solutions to the governing equations for single and two phase isothermal reactions in axial dispersion model reactors involving power-law type kinetics are presented. The solutions assume that the approximate solutions for the power-law type of kinetics are of the same forms

The application of the dispersion model of flow reactors for reactions of any order with two reactants and different initial concentrations yields a system of differential equations which can by considering the stoichiometry of the reaction be reduced to one differential equation. The numerical sol

## Abstrret -Plug flow as well as axml chspersion dynamic models for counter-flow extractwe reactors are formulated and solved to mvesmte the frequency response charactenstuzs of such reactors The reactions considered are taken to he either mfimtely fast, takmg place at the interface between the t