Adsorption breakthrough dynamics of zeolites for ethylene recovery from fluid catalytic cracking fuel-gas

The adsorption dynamics of zeolite 13X, 10X and 5A beds was investigated for recovering ethylene (C₂H₄) from fluidized catalytic cracking fuel-gas. As a feed gas, a ternary mixture (CH₄ : C₂H₄ : C₂H₆) and a model FCC fuel-gas (CH₄ : C₂H₄ : C₂H₆ : C₃H₆ : N₂ : H₂) were used for breakthrough experiments. In the ternary mixture, the concentration profiles showed similar patterns in all zeolite beds. C₂H₄ showed higher adsorption affinity than the others in all zeolites and zeolite 5A had the highest adsorption capacity of C₂H₄. In the six-component mixture, the breakthrough curves in the zeolite 5A bed showed similar patterns to the results of the ternary mixture. Although weak adsorbates could be removed during the adsorption step, CH₄ and N₂ imparted a steric hindrance to the initial stage of C₂H₄ adsorption in the zeolite 5A bed. Since vacuum desorption contributed to producing a high purity of C₂H₄, a pressure vacuum swing adsorption process was recommended to recover C₂H₄.