Polymer flocculation of calcite: Population balance model

A.R. Heath; P.A. Bahri; P.D. Fawell; J.B. Farrow

doi:10.1002/aic.10749

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Polymer flocculation of calcite: Population balance model

Journal article

Peer reviewed

Polymer flocculation of calcite: Population balance model

A.R. Heath, P.A. Bahri, P.D. Fawell and J.B. Farrow

AIChE Journal, Vol.52(5), pp.1641-1653

2006

DOI: https://doi.org/10.1002/aic.10749

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Abstract

A population balance (PB) model is used to describe the aggregation/breakage kinetics of calcite flocculation in turbulent pipe flow. The model describes simultaneous aggregation and breakage, and accounts for likely process variables: fluid shear, flocculant dosage, primary particle size and solid fraction, using four fitted parameters. Particle collision is described by the turbulent collision kernel of Saffman and Turner,1 however, the capture efficiency (α) is initially set to equal zero until the point of flocculant addition, then increases rapidly as described by an equation accounting for flocculant mixing/adsorption. Particles aggregated by high-molecular weight polymer flocculant typically do not achieve a steady-state aggregate size, where the rates of aggregation and breakage are equal. Instead, the aggregate size decreases gradually due to polymer chain scission or rearrangement on repeated aggregation/breakage. This phenomenon is accounted for in the model by a flocculant strength degradation term.

Details

Title: Polymer flocculation of calcite: Population balance model
Authors/Creators: A.R. Heath (Author/Creator)
P.A. Bahri (Author/Creator)
P.D. Fawell (Author/Creator)
J.B. Farrow (Author/Creator)
Publication Details: AIChE Journal, Vol.52(5), pp.1641-1653
Publisher: Wiley
Identifiers: 991005543969607891
Copyright: © 2006 American Institute of Chemical Engineers
Murdoch Affiliation: Parker Cooperative Research Centre for Integrated Hydrometallurgy Solutions
Language: English
Resource Type: Journal article

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Collaboration types: Domestic collaboration
Citation topics: 2 Chemistry; 2.90 Water Treatment; 2.90.1053 Coagulation-Flocculation
Web Of Science research areas: Engineering, Chemical
ESI research areas: Chemistry