A Model of Froth Flotation with Drainage: Simulations and Comparison with Experiments

Fernando Betancourt; Raimund Bürger; Stefan Diehl; Leopoldo Gutiérrez; M. Carmen Martí; Yolanda Vásquez

doi:10.3390/min13030344

A Model of Froth Flotation with Drainage: Simulations and Comparison with Experiments

Fernando Betancourt, Raimund Bürger, Stefan Diehl, Leopoldo Gutiérrez, M. Carmen Martí, Yolanda Vásquez

Research output: Contribution to journal › Article › peer-review

Abstract

The operation of a froth flotation column can be described by a nonlinear convection–diffusion partial differential equation that incorporates the solids–flux and drift–flux theories as well as a model of foam drainage. The resulting model predicts the bubble and (gangue) particle volume fractions as functions of height and time. The steady-state (time-independent) version of the model defines so-called operating charts that map conditions on the gas and pulp feed rates that allow for operation with a stationary froth layer. Operating charts for a suitably adapted version of the model are compared with experimental results obtained with a laboratory flotation column. Experiments were conducted with a two-phase liquid–bubble flow. The results indicate good agreement between the predicted and measured conditions for steady states. Numerical simulations for transient operation, in part for the addition of solid particles, are presented.

Original language	English
Article number	344
Journal	Minerals
Volume	13
Issue number	3
DOIs	https://doi.org/10.3390/min13030344
Publication status	Published - 2023 Mar

Subject classification (UKÄ)

Mathematical Sciences

Free keywords

drainage
drift flux
froth flotation
mathematical model
numerical simulation
partial differential equation
steady state

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10.3390/min13030344

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title = "A Model of Froth Flotation with Drainage: Simulations and Comparison with Experiments",

abstract = "The operation of a froth flotation column can be described by a nonlinear convection–diffusion partial differential equation that incorporates the solids–flux and drift–flux theories as well as a model of foam drainage. The resulting model predicts the bubble and (gangue) particle volume fractions as functions of height and time. The steady-state (time-independent) version of the model defines so-called operating charts that map conditions on the gas and pulp feed rates that allow for operation with a stationary froth layer. Operating charts for a suitably adapted version of the model are compared with experimental results obtained with a laboratory flotation column. Experiments were conducted with a two-phase liquid–bubble flow. The results indicate good agreement between the predicted and measured conditions for steady states. Numerical simulations for transient operation, in part for the addition of solid particles, are presented.",

keywords = "drainage, drift flux, froth flotation, mathematical model, numerical simulation, partial differential equation, steady state",

author = "Fernando Betancourt and Raimund B{\"u}rger and Stefan Diehl and Leopoldo Guti{\'e}rrez and Mart{\'i}, {M. Carmen} and Yolanda V{\'a}squez",

year = "2023",

month = mar,

doi = "10.3390/min13030344",

language = "English",

volume = "13",

journal = "Minerals",

issn = "2075-163X",

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TY - JOUR

T1 - A Model of Froth Flotation with Drainage

T2 - Simulations and Comparison with Experiments

AU - Betancourt, Fernando

AU - Bürger, Raimund

AU - Diehl, Stefan

AU - Gutiérrez, Leopoldo

AU - Martí, M. Carmen

AU - Vásquez, Yolanda

PY - 2023/3

Y1 - 2023/3

N2 - The operation of a froth flotation column can be described by a nonlinear convection–diffusion partial differential equation that incorporates the solids–flux and drift–flux theories as well as a model of foam drainage. The resulting model predicts the bubble and (gangue) particle volume fractions as functions of height and time. The steady-state (time-independent) version of the model defines so-called operating charts that map conditions on the gas and pulp feed rates that allow for operation with a stationary froth layer. Operating charts for a suitably adapted version of the model are compared with experimental results obtained with a laboratory flotation column. Experiments were conducted with a two-phase liquid–bubble flow. The results indicate good agreement between the predicted and measured conditions for steady states. Numerical simulations for transient operation, in part for the addition of solid particles, are presented.

AB - The operation of a froth flotation column can be described by a nonlinear convection–diffusion partial differential equation that incorporates the solids–flux and drift–flux theories as well as a model of foam drainage. The resulting model predicts the bubble and (gangue) particle volume fractions as functions of height and time. The steady-state (time-independent) version of the model defines so-called operating charts that map conditions on the gas and pulp feed rates that allow for operation with a stationary froth layer. Operating charts for a suitably adapted version of the model are compared with experimental results obtained with a laboratory flotation column. Experiments were conducted with a two-phase liquid–bubble flow. The results indicate good agreement between the predicted and measured conditions for steady states. Numerical simulations for transient operation, in part for the addition of solid particles, are presented.

KW - drainage

KW - drift flux

KW - froth flotation

KW - mathematical model

KW - numerical simulation

KW - partial differential equation

KW - steady state

U2 - 10.3390/min13030344

DO - 10.3390/min13030344

M3 - Article

AN - SCOPUS:85152396022

SN - 2075-163X

VL - 13

JO - Minerals

JF - Minerals

IS - 3

M1 - 344

ER -

A Model of Froth Flotation with Drainage: Simulations and Comparison with Experiments

Abstract

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