Modelling and simulation of the ion exchange process for Zn2+(aq) removal using zeolite NaY

Andrezza de Araújo Silva Gallindo; Reinaldo Alves da Silva Junior; Meiry Gláucia Freire Rodrigues; Wagner Brandão  Ramos

doi:10.33448/rsd-v10i12.20362

Authors

Andrezza de Araújo Silva Gallindo Federal University of Campina Grande https://orcid.org/0000-0001-7288-2311
Reinaldo Alves da Silva Junior Federal University of Pernambuco https://orcid.org/0000-0002-9592-3021
Meiry Gláucia Freire Rodrigues Federal University of Campina Grande https://orcid.org/0000-0003-2258-4230
Wagner Brandão Ramos Federal University of Campina Grande https://orcid.org/0000-0002-9375-6995

DOI:

https://doi.org/10.33448/rsd-v10i12.20362

Keywords:

Ion Exchange; NaY zeolite; Aspen Adsorption; Simulation; Kinetic modelling.

Abstract

The treatment of water contaminated by toxic metals using ion exchange with zeolites is becoming attractive due to its low capital costs and high potential for removal capacity. Mathematical modelling of this process allows for operational control and estimation of the ability to remove these metals. In this work, the kinetic modelling was performed based on finite bath experimental data, with Intraparticle Diffusion (IPD) and External Liquid Film Mass Transfer (MTEF) models. The models Thomas (TH), Yoon-Nelson (YN) and Solid Film Mass Transfer (MTSF) were used to estimate the saturation time, ion exchange capacity and sizing variables of a fixed bed column. For the finite bath system, the results showed that the mass transfer was better represented by the IPD phenomenon. The breakthrough curve obtained by the Aspen Adsorption (MTSF) model presented the best fit, compared with experimental data, with R²≥0.9923. The average ion exchange capacities calculated for MTSF, TH and YN were respectively 2.22, 2.12 and 2.07 meq Zn²⁺(aq)/ g of zeolite. The model simulated with Aspen Adsorption was also used to analyze the continuous system behaviour, by varying the height of the bed. It was observed that increasing the height, the saturation time and ion exchange capacity also increase, while reducing the height makes axial dispersion the predominant mass transfer phenomenon, which reduces the diffusion of Zn²⁺(aq) ions.

Author Biographies

Andrezza de Araújo Silva Gallindo, Federal University of Campina Grande

Chemical Engineering Department

Reinaldo Alves da Silva Junior, Federal University of Pernambuco

Department of Biochemistry

Meiry Gláucia Freire Rodrigues, Federal University of Campina Grande

Chemica Engineering Department

Wagner Brandão Ramos, Federal University of Campina Grande

Chemical Engineering Department

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Modelling and simulation of the ion exchange process for Zn2+(aq) removal using zeolite NaY

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DOI:

Keywords:

Abstract

Author Biographies

Andrezza de Araújo Silva Gallindo, Federal University of Campina Grande

Reinaldo Alves da Silva Junior, Federal University of Pernambuco

Meiry Gláucia Freire Rodrigues, Federal University of Campina Grande

Wagner Brandão Ramos, Federal University of Campina Grande

References

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