Integrated Process for Production of Surfactin(III)Modeling of Adsorption Column

摘要/Abstract

摘要： The study is focused on modeling of separation process and optimization.An adsorption separation process is simulated.The surfactin production process by Bacillus subtilis ATCC 21332 followed by surfactin adsorption in a fixed-bed column packed with commercial active carbon is studied in laboratory.The adsorption column achieves high surfactin recovery(94%)by up-flow methanol elution at 25℃.The adsorption column is simulated with a complex one-dimensional plug flow dispersion model coupled with nonlinear adsorption equilibrium,based on the assumption that the adsorption of surfactin is monomolecular layer and no micelle is formed.The molecular diffusion coefficient of surfactin in water solution with electric neutrality is estimated to be 0.428×10^-5cm²·s^-1 by molecular dynamics simulation.The model developed can describe the complex interplay of adsorption kinetics,fluid dynamics,and mass-transfer phenomena based on the assumption of no radial temperature and concentration gradients,and is of adequate precision.The work involved in this paper is valuable for the optimization of the production process of surfactin.

关键词: surfactant, adsorption, mathematical modelling, kinetics, integrated process

Abstract: The study is focused on modeling of separation process and optimization.An adsorption separation process is simulated.The surfactin production process by Bacillus subtilis ATCC 21332 followed by surfactin adsorption in a fixed-bed column packed with commercial active carbon is studied in laboratory.The adsorption column achieves high surfactin recovery(94%)by up-flow methanol elution at 25℃.The adsorption column is simulated with a complex one-dimensional plug flow dispersion model coupled with nonlinear adsorption equilibrium,based on the assumption that the adsorption of surfactin is monomolecular layer and no micelle is formed.The molecular diffusion coefficient of surfactin in water solution with electric neutrality is estimated to be 0.428×10^-5cm²·s^-1 by molecular dynamics simulation.The model developed can describe the complex interplay of adsorption kinetics,fluid dynamics,and mass-transfer phenomena based on the assumption of no radial temperature and concentration gradients,and is of adequate precision.The work involved in this paper is valuable for the optimization of the production process of surfactin.

Key words: surfactant, adsorption, mathematical modelling, kinetics, integrated process

Ludovic Montastruc, 刘涛, Iordan Nikov, Pascal Floquet, Serge Domenech. Integrated Process for Production of Surfactin(III)Modeling of Adsorption Column[J]. , 2011, 19(3): 357-364.

Ludovic Montastruc, LIU Tao, Iordan Nikov, Pascal Floquet, Serge Domenech. Integrated Process for Production of Surfactin(III)Modeling of Adsorption Column[J]. , 2011, 19(3): 357-364.

参考文献

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