Linear driving force approximation for isothermal non-isobaric diffusion/convection with binary Langmuir adsorption

Gas Separation & Purification Pub Date : 1995-12-01 DOI:10.1016/0950-4214(95)00008-Y

A.M.M. Mendes, C.A.V. Costa, A.E. Rodrigues

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引用次数: 21

Abstract

This paper presents several reduced models for the intraparticle diffusion/convection mechanisms in spherical homoporous particles under isothermal conditions. These semi-empirical linear driving force approximations were developed for the cyclic steady state that is attained when a cyclic concentration and/or total pressure perturbation is imposed at the particle surface. The models are applicable to linear systems or those obeying bicomponent Langmuir isotherms. The linear driving force approximations have two or three parameters for each component and are presented for the following cases: Knudsen diffusion, molecular diffusion, molecular plus Knudsen diffusion in series, viscous flow, and also for both diffusion mechanisms in series, in parallel with the convective flow, as in the dusty gas model. Comparison between the results obtained with these approximations and with the complete models shows that on average the relative quadratic error is ≈10% for non-smooth and 5% for smoother perturbations.

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二元Langmuir吸附等温非等压扩散/对流的线性驱动力近似

本文提出了等温条件下球形均孔颗粒颗粒内扩散/对流机制的几种简化模型。这些半经验线性驱动力近似是为在颗粒表面施加循环浓度和/或总压力扰动时获得的循环稳态而开发的。该模型适用于线性系统或服从双分量朗缪尔等温线的系统。线性驱动力近似对每个成分都有两个或三个参数，适用于以下情况:Knudsen扩散、分子扩散、分子加Knudsen扩散串联、粘性流动，以及两种扩散机制串联，与对流流动平行，如在含尘气体模型中。用这些近似得到的结果与完整模型的比较表明，非光滑扰动的相对二次误差平均为≈10%，光滑扰动的相对二次误差平均为5%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Gas Separation & Purification

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