On the development of a consistent mathematical model for adsorption in a packed column (and why standard models fail)

•Analytical solution describing fluid extraction from an adsorption column.•Excellent agreement with a range of experimental data.•Proof that previous accepted models do not work.•Demonstration that to accurately characterise experiments both breakthrough and isotherm data are required.•Development...

Full description

Saved in:
Bibliographic Details
Published in:International journal of heat and mass transfer 2023-03, Vol.202, p.123660, Article 123660
Main Authors: Myers, Timothy G., Cabrera-Codony, Alba, Valverde, Abel
Format: Article
Language:English
Subjects:
Adsorption
Advection-diffusion
Bohart–Adams
Contaminant removal
Mathematical model
Pollutant removal
Travelling wave
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Analytical solution describing fluid extraction from an adsorption column.•Excellent agreement with a range of experimental data.•Proof that previous accepted models do not work.•Demonstration that to accurately characterise experiments both breakthrough and isotherm data are required.•Development of a novel analytical solution including a SIPS mass sink. In this paper we investigate the standard one-dimensional model for adsorption of a contaminant in a packed column. Initially we focus on two mass sink models: a full nonlinear Langmuir equation, including adsorption and desorption and the linearised version which neglects the local concentration. Travelling wave solutions are developed for both cases, providing exact analytical formulae for the concentration and adsorbed fraction throughout the column. Comparison is made with experimental data for the adsorption of toluene on activated carbon (dominated by physical adsorption) and Cr(III) on zeolite NaX (dominated by ion exchange). For toluene the nonlinear model provides good agreement but it is less accurate for Cr(III). The linear model apparently works well for Cr(III) but only at the expense of violating the model assumptions. This motivates extending the travelling wave solution to a Sips sink model, which has a power law dependence on local concentration. Comparison with data provides excellent agreement in all cases and also indicates why the previous models fail. Following from the investigation of the linear sink model, we prove that previously accepted results frequently fail due to a violation of assumptions made in their derivation. Specifically we challenge the belief that widely used models such as Bohart–Adams, Yoon–Nelson, Bed Depth Service Time, etc can accurately predict breakthrough data. Their success instead may be attributed to: at times, having a similar shape to the breakthrough curve rather than being the correct solution; treating measurable quantities as fitting parameters and a willingness to accept that constant parameters vary. In contrast to these previous models, the travelling wave solution of the present paper, based on a Sips sink, provides analytical solutions consistent with the model assumptions for a wide range of experimental data.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2022.123660