Equilibrium and kinetic analysis of CO 2–N 2 adsorption separation by concentration pulse chromatography

Abstract

CO 2 and N 2 adsorption kinetics and equilibrium behaviours have been studied with silicalite, NaY and 13X by using concentration pulse chromatography for the separation of these gases in the present study. Adsorption Henry's Law constants, the heat of adsorption values, micropore diffusion coefficients and corresponding activation energies are determined experimentally and the three different mass transfer mechanisms are discussed. From the equilibrium data, the corresponding separation factors are obtained for the adsorption separation processes. The heat of adsorption values as well as the Henry's Law adsorption equilibrium constants of CO 2 are much higher than those of N 2 for all the adsorbents studied. 13X, NaY and silicalite all have good separation factors for CO 2/N 2 system based on equilibrium processes. The order of the equilibrium separation factors is 13X (Ceca) > 13X (Zeochem) > NaY (UOP) ≫ silicalite (UOP). Equilibrium selectivity favours CO 2 over N 2. Micropore diffusion resistance is the definite dominant mass transfer mechanism for CO 2 with silicalite and NaY.