Flotation Cell (Savassi): Difference between revisions

Description

This article describes a model that estimates the recovery of ore and gangue from a mechanical flotation cell.

The approach is outlined by Savassi (2005), who proposed a compartment model that separates the mechanisms of true flotation, froth recovery, and entrainment.^[1]

Savassi's original model was further extended over many years by subsequent researchers, and the resulting methodology is frequently referred to as the "P9 model" in reference to the AMIRA P9 project that has driven much of the development since.^[2]

Model theory

Floatability classes

Much of the original literature underpinning the modelling approach described here refers to the notion of a floatability class, which groups all particles that exhibit similar floatability properties, without any particular reference to particle sizes or mineral compositions within the class.^[3] In order to align the flotation modelling approach with the comminution, classification and concentration processes described in other articles, a distinction is made between particle size and floatability component.

The mathematical relations below are developed on the basis of a particle size class which is further subdivided into floatability components. This allows the definition of floatability rate groups (e.g. fast, slow, non-floating) within mineral types (e.g. chalcopyrite, pyrite, non-sulphide gangue), by size fraction.

Recovery

Savassi's compartment model describes the recovery of particles by the mechanisms of true flotation, froth mass transfer and entrainment.

The compartment model may be formulated for both batch/plug flow and continuous (perfectly mixed) flow patterns.^[3][4]

Recovery is expressed as:

${\displaystyle R_{ij}={\begin{cases}1-\exp \left(-P_{ij}\cdot (S_{\rm {b}}\cdot 60)\cdot Rf_{ij}\cdot C_{ij}\cdot \tau \right)\cdot (1-{\rm {ENT}}_{ij}\cdot R_{\rm {w}})&{\text{for batch or plug flow flotation}}\\\\{\dfrac {P_{ij}\cdot (S_{\rm {b}}\cdot 60)\cdot Rf_{ij}\cdot C_{ij}\cdot \tau \cdot (1-R_{\rm {w}})+{\rm {ENT}}_{ij}\cdot R_{\rm {w}}}{(1+P_{ij}\cdot (S_{\rm {b}}\cdot 60)\cdot Rf_{ij}\cdot C_{ij}\cdot \tau )(1-R_{\rm {w}})+{\rm {ENT}}_{ij}\cdot R_{\rm {w}}}}&{\text{for continuous flotation}}\\\end{cases}}}$

where:

• ${\displaystyle i}$ is the index of the size interval, ${\displaystyle i=\{1,2,\dots ,n\}}$, ${\displaystyle n}$ is the number of size intervals
• ${\displaystyle j}$ is the index of the floatability component, ${\displaystyle j=\{1,2,\dots ,m\}}$, ${\displaystyle m}$ is the number of floatability components (e.g. mineral types, fast/slow types etc.)
• ${\displaystyle R_{ij}}$ is the fraction of particles of size fraction ${\displaystyle i}$ and floatability component type ${\displaystyle j}$ recovered to concentrate (frac)
• ${\displaystyle P_{ij}}$ is the floatability of particles of size ${\displaystyle i}$ and floatability component type ${\displaystyle j}$ (frac)
• ${\displaystyle S_{\rm {b}}}$ is the bubble surface area flux (m²/s/m²)
• ${\displaystyle Rf_{ij}}$ is the fraction of particles of size ${\displaystyle i}$ and floatability component ${\displaystyle j}$ recovered by froth (frac)
• ${\displaystyle C_{ij}}$ is a cell scale-up factor that relates flotation performance between cells of different sizes (e.g. laboratory versus industrial) (frac)
• ${\displaystyle \tau }$ is the residence time of slurry in the cell (min)
• ${\displaystyle {\rm {ENT}}_{ij}}$ is the fraction of particles of size ${\displaystyle i}$ and floatability component ${\displaystyle j}$ recovered by entrainment (frac)
• ${\displaystyle R_{\rm {w}}}$ is the fraction of feed water recovered to concentrate (frac)

The cell scale-up factor, ${\displaystyle C_{ij}}$, allows for the simulation of industrial-scale cells using kinetic rates derived from laboratory cells.^[5]

Pulp volume

Pulp volume, ${\displaystyle V_{\rm {effective}}}$ (m³), is related to cell paramters.

${\displaystyle V_{\rm {effective}}=(V_{\rm {cell}}-V_{\rm {mechanism}}-A_{\rm {cell}}*H_{\rm {f}})\cdot (1-\varepsilon _{\rm {gas}})}$

where:

• ${\displaystyle V_{\rm {cell}}}$ is the total volume of the cell
• ${\displaystyle V_{\rm {mechanism}}}$ is the volume of the impeller mechanism in the cell (m³)
• ${\displaystyle A_{\rm {cell}}}$ is the cross sectional area of the cell (m²)
• ${\displaystyle H_{\rm {f}}}$ is the froth depth from the top of the cell (m)
• ${\displaystyle \varepsilon _{\rm {gas}}}$ is the gas hold-up in the pulp (v/v)

Gas hold-up

Gas hold-up, ${\displaystyle \varepsilon _{\rm {gas}}}$ (v/v), may be estimated from a linear relationship as suggested by the findings of Gorain et al. (1995):^[6]

${\displaystyle \varepsilon _{\rm {gas}}=m_{\rm {gas}}\cdot J_{\rm {g}}+C_{\rm {gas}}}$

where ${\displaystyle m_{\rm {gas}}}$ and ${\displaystyle C_{\rm {gas}}}$ are the slope an intercept parameters, respectively, of the linear equation.

The superficial gas rate, ${\displaystyle J_{\rm {g}}}$ (m/s), is approximated by:^[7]

${\displaystyle J_{\rm {g}}={\dfrac {Q_{\rm {air}}}{A_{\rm {cell}}\cdot 60\cdot 60}}}$

where ${\displaystyle Q_{\rm {air}}}$ is the air rate (m³/h).

Residence time

Residence time, ${\displaystyle \tau }$ (min), may be computed on the basis of the cell feed or tailing stream volumetric flow rates.^[8]

${\displaystyle \tau ={\begin{cases}{\dfrac {V_{\rm {effective}}}{Q_{\rm {feed}}\cdot 60}}&{\text{for feed-based residence time}}\\\\{\dfrac {V_{\rm {effective}}}{Q_{\rm {tail}}\cdot 60}}&{\text{for tail-based residence time}}\\\end{cases}}}$

where ${\displaystyle {Q_{\rm {feed}}}}$ and ${\displaystyle {Q_{\rm {tail}}}}$ are the volumetric flow rates of pulp in the feed and tail streams, respectively (m³/h).

The volumetric flow rate of the tailing stream is a function of the recoveries of solids computed by the Savassi equation and water. As such, an iterative procedure is required to estimate the tail-based residence time.

Bubble surface area flux

The bubble surface area flux, ${\displaystyle S_{\rm {b}}}$ (m²/s/m²), is related to the superficial gas rate, ${\displaystyle J_{\rm {g}}}$, and Sauter mean bubble diameter, ${\displaystyle d_{\rm {b}}}$ (m), by the equation:

${\displaystyle S_{\rm {b}}={\dfrac {6J_{\rm {g}}}{d_{\rm {b}}}}}$

The Sauter mean bubble diameter may be determined from gas dispersion measurements. Where a measurement of ${\displaystyle d_{\rm {b}}}$ is not available, ${\displaystyle S_{\rm {b}}}$ may be estimated by the empirical relation of Gorain et al. (1999):^[7]

${\displaystyle S_{\rm {b}}=123{N_{\rm {s}}}^{0.44}{J_{\rm {g}}}^{0.75}{A_{\rm {s}}}^{-0.10}{P_{80}}^{-0.42}}$

where:

• ${\displaystyle N_{\rm {s}}}$ is impeller tip speed (m/s)
• ${\displaystyle A_{\rm {s}}}$ is impeller aspect ratio (m/m), the ratio of impeller diameter (m) to impeller height (m)
• ${\displaystyle P_{80}}$ is the size that 80% of solid particles in the feed are finer than (µm)

The Gorain relation may be modified to suit alternative bubble surface area flux data sets with:

${\displaystyle S_{\rm {b}}=C_{\rm {Sb}}{N_{\rm {s}}}^{a}{J_{\rm {g}}}^{b}{As}^{c}{P_{80}}^{d}}$

where ${\displaystyle C_{\rm {Sb}}}$ and ${\displaystyle a\dots d}$ are a user-defined coefficient and set of exponents, respectively.

Froth recovery

Froth recovery, ${\displaystyle Rf_{ij}}$, may be estimated using the froth residence time model outlined by Harris et al. (2002).^[9]

${\displaystyle Rf_{ij}=(1-(P_{\rm {d}})_{j})+(P_{\rm {d}})_{j}\cdot {\rm {ENT}}_{i}\cdot R_{\rm {w}}}$

where ${\displaystyle (P_{\rm {d}})_{j}}$ is the probability of detachment of ore type ${\displaystyle j}$ (frac), computed as:

${\displaystyle (P_{\rm {d}})_{j}=1-\exp(-\beta _{j}\cdot {\rm {FRT}})}$

and ${\displaystyle \beta _{j}}$ is the detachment rate constant (min^-1) for ore type ${\displaystyle j}$.

The froth residence time, ${\displaystyle FRT}$ (min), is computed based on either air or slurry flow rates:

${\displaystyle {\rm {FRT}}={\begin{cases}{\dfrac {H_{\rm {f}}\cdot {\varepsilon _{\rm {froth}}}}{J_{\rm {g}}}}&{\text{for air-based froth residence time}}\\{\dfrac {H_{\rm {f}}\cdot A_{\rm {cell}}\cdot (1-\varepsilon _{\rm {froth}})}{Q_{\rm {con}}}}&{\text{for slurry-based froth residence time}}\\\end{cases}}}$

where ${\displaystyle \varepsilon _{\rm {froth}}}$ is the gas hold-up fraction in the froth phase (v/v), and ${\displaystyle Q_{\rm {con}}}$ is the volumetric flow rate of concentrate from the cell.

The concentrate flow rate, ${\displaystyle Q_{\rm {con}}}$, is a function of the recoveries of solids computed by the Savassi equation and water. As with the tail-based residence time (see above), an iterative procedure is required to estimate froth recovery via the froth residence time method (even if a feed-basis is used to estimate pulp residence time).

Entrainment

Entrainment may be estimated by two methods, the hyperbolic equation approach by Savassi et al. (1998), and the froth residence time approach described by Vera et al (2002).^[10][11]

The hyperbolic equation for entrainment is:

${\displaystyle {\rm {ENT}}_{i}={\dfrac {2}{\exp \left(2.292\left({\dfrac {{\bar {d}}_{i}}{E20}}\right)^{adj}\right)+\exp \left(-2.292\left({\dfrac {{\bar {d}}_{i}}{E20}}\right)^{adj}\right)}}}$

${\displaystyle adj=1+{\dfrac {\ln \delta }{\exp \left({\dfrac {{\bar {d}}_{i}}{E20}}\right)}}}$

where:

• ${\displaystyle {\bar {d}}_{i}}$ is the geometric mean size of particles in size interval ${\displaystyle i}$ (µm)
• ${\displaystyle E20}$ is the particle size at which ${\displaystyle {\rm {ENT}}_{i}}$ is 0.2 (µm)
• ${\displaystyle \delta }$ is the froth drainage parameter

The froth residence time approach first computes the froth residence time (${\displaystyle {\rm {FRT}}}$) according to the method descibed for froth recovery above. Entrainment is then estimated by applying the following equation:

${\displaystyle {\rm {ENT}}_{i}={\dfrac {1}{1+\omega _{i}\cdot {\rm {FRT}}}}}$

where ${\displaystyle \omega _{i}}$ is the froth drainage factor for particles in size interval ${\displaystyle i}$ (min^-1).

When the effects of entrainment are ignored, the recovery equation reduces to:

${\displaystyle R_{ij}={\begin{cases}1-\exp \left(-P_{ij}\cdot (S_{\rm {b}}\cdot 60)\cdot Rf_{ij}\cdot C_{ij}\cdot \tau \right)&{\text{for batch or plug flow flotation}}\\\\{\dfrac {P_{ij}\cdot (S_{\rm {b}}\cdot 60)\cdot Rf_{ij}\cdot C_{ij}\cdot \tau }{(1+P_{ij}\cdot (S_{\rm {b}}\cdot 60)\cdot Rf_{ij}\cdot C_{ij}\cdot \tau )}}&{\text{for continuous flotation}}\\\end{cases}}}$

Water recovery

Methods for estimating the recovery of water are described by Harris et al. (2002).^[9]

The fixed concentrate percent solids method assumes the concentrate is always recovered at a fixed pulp density. The recovery of water, ${\displaystyle R_{\rm {w}}}$, is then computed to meet the fixed concentrate solids fraction requirement.

The solids dependent model assumes a power law relationship between the volumetric flow rate of water, ${\displaystyle Q_{\rm {w}}}$ (m³/h), and solids, ${\displaystyle Q_{\rm {s}}}$ (m³/h), in the concentrate stream:

${\displaystyle Q_{\rm {w}}=a_{\rm {w}}\cdot {Q_{\rm {s}}}^{b_{\rm {w}}}}$

where ${\displaystyle a}$ and ${\displaystyle b}$ are the coefficient and exponent of the power law relationship, respectively.

Finally, the water rate function adopts a first order kinetic relationship between water recovery and pulp residence time:

${\displaystyle R_{\rm {w}}={\dfrac {k_{\rm {w}}\tau }{1+k_{\rm {w}}\tau }}}$

where ${\displaystyle k_{\rm {w}}}$ is the kinetic rate parameter (min^-1) for the recovery of water to the concentrate stream.

Excel

The Savassi flotation cell model may be invoked from the Excel formula bar with the following function call:

=mdUnit_Flotation_Savassi(Parameters as Range, Size as Range, Feed as Range, OreSG As Range, Floatability as Range, Optional CellScaleUp As Range = Nothing, Optional FrothRecovery as Range = Nothing, Optional Entrainment as Range = Nothing, Optional DetachRateConst as Range = Nothing, Optional DrainageFactor as Range = Nothing)

Several of the function input parameters are marked as Optional:

• If CellScaleUp is omitted, cell scale up ignored and ${\displaystyle C_{ij}=1}$ for all ${\displaystyle i}$ and ${\displaystyle j}$
• If FrothRecovery is omitted, froth recovery is ignored and ${\displaystyle Rf_{ij}=1}$ for all ${\displaystyle i}$ and ${\displaystyle j}$
• If Entrainment is omitted, recovery by entrainment is ignored and ${\displaystyle {\rm {ENT}}_{ij}=0}$ for all ${\displaystyle i}$ and ${\displaystyle j}$
• If DetachRateConst is omitted, ${\displaystyle \beta _{j}=0}$ for all ${\displaystyle j}$
• If DrainageFactor is omitted, ${\displaystyle \omega _{i}=0}$ for all ${\displaystyle i}$

Invoking the function with no arguments will print Help text associated with the model, including a link to this page.

Inputs

The required inputs are defined below in matrix notation with elements corresponding to cells in Excel row (${\displaystyle i}$) x column (${\displaystyle j}$) format: