Stirred Mill (Perfect Mixing, Dynamic): Difference between revisions

Description

This article describes a dynamic implementation of the Perfect Mixing vertical stirred mill model outlined by Napier-Munn et al. (1996).^[1]

The dynamic version uses the same underlying theory and structure as the steady-state Perfect Mixing stirred mill model. For a full description of the steady-state model, see Stirred Mill (Perfect Mixing).

Model theory

The dynamic Perfect Mixing model is based on a population balance of particles entering the mill, breaking into smaller sizes, and discharging as product. For a mill operating in unsteady-state, the diagram in Figure 1 below represents the balance for a given size fraction:

Figure 1. Schematic diagram of the population balance adopted by the dynamic Perfect Mixing model.

The dynamic population balance is described mathematically as:^[2]

${\displaystyle {\frac {ds_{i}(t)}{dt}}=f_{i}-D_{i}s_{i}+\sum _{j=1}^{i-1}A_{ij}R_{j}s_{j}-(R_{i}s_{i}-A_{ii}R_{i}s_{i})}$

${\displaystyle p_{i}=D_{i}s_{i}}$

where:

• ${\displaystyle i}$ is the index of the size interval, ${\displaystyle i=\{1,2,\dots ,n\}}$, ${\displaystyle n}$ is the number of size intervals
• ${\displaystyle f_{i}}$ is the mass feed rate of solids in size interval ${\displaystyle i}$
• ${\displaystyle p_{i}}$ is the mass product rate of solids in size interval ${\displaystyle i}$
• ${\displaystyle s_{i}}$ is the mass of solids in the mill load in size interval ${\displaystyle i}$
• ${\displaystyle R_{i}}$ is the breakage rate of solids in the mill load in size interval ${\displaystyle i}$
• ${\displaystyle D_{i}}$ is the rate of discharge from the mill of solids in size interval ${\displaystyle i}$
• ${\displaystyle A_{ij}}$ is the Appearance function, the distribution of particle mass arising from the breakage of a parent particle in size interval ${\displaystyle j}$ into progeny of size interval ${\displaystyle i}$

Unlike the steady-state version, the load component ${\displaystyle s_{i}}$ cannot be eliminated from the equation, nor can the ${\displaystyle R_{i}}$ and ${\displaystyle D_{i}}$ components be combined into a single ${\displaystyle R_{i}/D_{i}}$ term. Therefore, the breakage and discharge rates ${\displaystyle R_{i}}$ and ${\displaystyle D_{i}}$ must be specified separately as inputs to the dynamic model.

Finally, an unsteady-state mill simulation must also consider the retention of liquids in the load:

${\displaystyle {\frac {ds_{\rm {w}}(t)}{dt}}=f_{\rm {w}}-D_{\rm {w}}s_{\rm {w}}}$

where:

• ${\displaystyle s_{\rm {w}}}$ is the load mass of water in the mill
• ${\displaystyle f_{\rm {w}}}$ is the mass feed rate of water into the mill
• ${\displaystyle D_{\rm {w}}}$ is the discharge rate of water from the mill, normally assumed to equal the value of ${\displaystyle D_{i}}$ at the finest size interval.

Time step discretisation

The unsteady-state Perfect Mixing differential equation is numerically solved by a discretised time stepping approach (i.e. Euler's method). The change in load mass in a size fraction ${\displaystyle \Delta s_{i}}$ during a sufficiently small time increment ${\displaystyle \Delta t=t_{n+1}-t_{n}}$ is:

${\displaystyle \Delta s_{i}=\left(f_{i}-D_{i}s_{i}+\sum _{j=1}^{i-1}A_{ij}R_{j}s_{j}-(R_{i}s_{i}-A_{ii}R_{i}s_{i})\right).\Delta t}$

Similarly, for liquids:

${\displaystyle \Delta s_{w}=\left(f_{w}-D_{w}s_{w}\right).\Delta t}$

The time stepping approach is a convenient numerical approximation to the solution of the unsteady-state Perfect Mixing population balance differential equation. The approach is, however, subject to several limitations:

• The mass of particles separately discharged from or broken out of a size interval in a time step cannot exceed the mass of particles actually present in that size interval.
• Similarly, the overall maximum discharge flow rate of pulp from the mill cannot exceed the total volume of pulp in the mill in a time step.

The time step size used internally by the model is automatically reduced to ensure the breakage, discharge and pulp flow rate limits per step are not exceeded. This is achieved by computing a number of sequential sub-steps at the reduced internal step size for each requested external step.

This is useful if the either a fixed time step specified by an application is too large (e.g. SysCAD) or a numerical solution is desired in as few steps as possible (e.g. Excel). The automatic time step adjustment is largely invisible to the user and manifests only as a slightly slower execution speed.

The calculated time step size may be overridden with a larger user-specified sub-step count if increased accuracy in the numerical approximation is desired.

Breakage rate

Figure 2. Schematic of a bottom-fed, gravity-induced vertical stirred mill showing key dimensions. The stirrer shown is a screw type with two starts and three turns per start. (After Napier-Munn et al., 1996).^[1]

The breakage function, ${\displaystyle R_{i}}$, is an input parameter for the dynamic Perfect Mixing model, replacing the ${\displaystyle R_{i}/D_{i}}$ term appearing in the steady-state version.

The breakage rate, ${\displaystyle R_{i}}$, is affected by mill operating conditions as follows:

${\displaystyle R_{i}\propto {\dfrac {{D_{\rm {s}}}^{3}H_{\rm {b}}N_{\rm {s}}TS}{D_{\rm {b}}}}}$

• ${\displaystyle D_{\rm {s}}}$ is the stirrer diameter (m)
• ${\displaystyle N_{\rm {s}}}$ is the stirrer speed (rpm)
• ${\displaystyle S}$ is the number of starts of the screw stirrer
• ${\displaystyle T}$ is the number of turns per start along the full height of the screw stirrer (${\displaystyle H}$)
• ${\displaystyle D_{\rm {b}}}$ is the mean media diameter (mm)

Adopting the same scaling approach and nomenclature as the Perfect Mixing ball mill, the ${\displaystyle R_{i}^{*}}$ rate is scaled by the following relation:

${\displaystyle \left({\frac {R}{D^{*}}}\right)_{\rm {Sim}}=\left({\frac {R}{D^{*}}}\right)_{\rm {Orig}}\cdot f_{\rm {Ds}}\cdot f_{\rm {Hb}}\cdot f_{\rm {Ns}}\cdot f_{\rm {S}}\cdot f_{\rm {T}}\cdot f_{\rm {Db}}\cdot f_{\rm {WI}}}$

The scaling factors are defined as:

${\displaystyle {\begin{array}{lll}f_{\rm {Ds}}=\left({\dfrac {(D_{\rm {s}})_{\rm {Sim}}}{(D_{\rm {s}})_{\rm {Orig}}}}\right)^{e_{1}},&&f_{\rm {Hb}}=\left({\dfrac {(H_{\rm {b}})_{\rm {Sim}}}{(H_{\rm {b}})_{\rm {Orig}}}}\right)^{e_{2}},&&f_{\rm {Ns}}=\left({\dfrac {(N_{\rm {s}})_{\rm {Sim}}}{(N_{\rm {s}})_{\rm {Orig}}}}\right)^{e_{3}}\\f_{\rm {S}}=\left({\dfrac {S_{\rm {Sim}}}{S_{\rm {Orig}}}}\right)^{e_{4}},&&f_{\rm {T}}=\left({\dfrac {T_{\rm {Sim}}}{T_{\rm {Orig}}}}\right)^{e_{5}},&&f_{\rm {Db}}=\left({\dfrac {(D_{\rm {b}})_{\rm {Orig}}}{(D_{\rm {b}})_{\rm {Sim}}}}\right)^{e_{6}}\\f_{\rm {WI}}=\left({\frac {{\rm {WI}}_{\rm {Orig}}}{{\rm {WI}}_{\rm {Sim}}}}\right)^{e_{7}}\end{array}}}$

where:

• the ${\displaystyle {\rm {Orig}}}$ subscript refers to the original mill from which ${\displaystyle R_{i}/D_{i}^{*}}$ was derived
• the ${\displaystyle {\rm {Sim}}}$ subscript refers to the mill being simulated (scaled)
• ${\displaystyle e_{1}\dots e_{7}}$ are scaling exponents, ${\displaystyle e_{1}=3}$, ${\displaystyle e_{2}\dots e_{6}=1}$, and ${\displaystyle e_{7}=0.8}$

The Work Index scaling factor, ${\displaystyle f_{\rm {WI}}}$, is retained from the Perfect Mixing ball mill model, where ${\displaystyle {\rm {WI}}}$ is the Bond Ball Work Index value of the ore (kWh/t).

The model user may optionally change the values of ${\displaystyle e_{1}\dots e_{7}}$ to suit specific test work results or operating data.

The discharge rate scaling factor, ${\displaystyle D^{*}}$, is excluded from the breakage rate scaling term and is dealt with separately within the model (see Slurry filling and discharge, below).

Discharge rate

The classical Leung definition of discharge rate of solids from a perfectly mixed mill is:^[3]

${\displaystyle p_{i}=D_{i}.s_{i}}$

where:

${\displaystyle D_{i}=d_{\rm {max}}.C_{i}}$

${\displaystyle C_{i}={\begin{cases}1&{\bar {d}}_{i}<x_{\rm {m}}\\1-{\dfrac {\ln {\bar {d}}_{i}-\ln x_{\rm {m}}}{\ln x_{\rm {g}}-\ln x_{\rm {m}}}}&x_{\rm {m}}<{\bar {d}}_{i}<x_{\rm {g}}\\0&{\bar {d}}_{i}>x_{\rm {g}}\\\end{cases}}}$

and:

• ${\displaystyle d_{\rm {max}}}$ is the fraction of load presented to the mill discharge per unit of time (h^-1)
• ${\displaystyle C_{i}}$ is the classification function, the fraction of particles of size ${\displaystyle i}$ reporting to the mill product (frac)
• ${\displaystyle {\bar {d}}_{i}}$ is the geometric mean size of particles in size interval ${\displaystyle i}$ (mm)
• ${\displaystyle x_{\rm {m}}}$ is the particle size below which all mass in the size interval reports to mill product (mm), i.e. like water
• ${\displaystyle x_{\rm {g}}}$ is the largest particle size which can report to mill product (mm)

Prior work suggests that internal classification within stirred mills may be represented by a Whiten efficiency curve (Hasan et al., 2016).^[4] Leung's equation is likely to be an adequate approximation of the same classification behaviour.

Appearance function

Figure 3. Standard appearance functions for ball (Broadbent-Calcott) and stirred (Kelsall) mills (after Morrell et al., 1993.^[5]

The Appearance function describes the mass-by-size distribution of progeny particles resulting from the breakage of parent particles.

The Appearance function may be specified for a particular ore.

Morrell et al. (1993) found the appearance functions generated for the Perfect Mixing ball mill model were too fine for stirred mills. They recommended either generating new appearance functions at one-tenth of the standard breakage test input energy level, or using the Kelsall breakage function.^[5]

Internal mesh series

The Perfect Mixing mill model is formulated internally with a geometric progression of 31 mesh sizes at ${\displaystyle {\sqrt {2}}}$ intervals. Feed and product size fractions are automatically converted to and from the internal mesh series during model computation. The ${\displaystyle {\sqrt {2}}}$ size intervals allow the appearance function to be specified as a one-dimensional matrix, rather than the two dimensional form defined above, since

${\displaystyle A_{ij}=A_{i-j}}$

when the intervals are so spaced.

Multi-component modelling

The original Perfect Mixing model formulation only considered the properties of a single ore type.

This implementation applies different appearance functions and breakage rate scaling factors to separate population balance computations for each ore type in the feed.

Slurry filling and discharge

The unsteady-state population balance and liquid hold-up models described above compute the quantity of slurry in the mill at each discrete time step.

Discharge flow does not commence from an initially empty stirred mill until the available internal volume is filled. The available internal volume consists of the grinding media interstices and any remaining space above the media charge.

The discharge rate, ${\displaystyle D_{i}}$, whilst filling the mill is zero. During this period, the dynamic population balance reduces to a batch mill formulation (with or without feed), as outlined by Whiten (1974):^[6]

${\displaystyle {\frac {ds_{i}(t)}{dt}}=f_{i}+\sum _{j=1}^{i-1}A_{ij}R_{j}s_{j}-(R_{i}s_{i}-A_{ii}R_{i}s_{i})}$

Discharge commences once the internal mill volume is filled with slurry. The volumetric discharge rate of pulp from the mill is then, for practical purposes, equal to the instantaneous volumetric feed rate.

The model computes the value of ${\displaystyle d_{\rm {max}}}$ to ensure the total flow rate of water plus solids classified for discharge matches the required product pulp outflow rate (i.e. the feed rate) for the mill.

Excel

The Perfect Mixing stirred mill model is not implemented in Excel in dynamic form for practical purposes. Excel is not an ideal platform for dynamic simulation and SysCAD (or similar) is preferred.

The dynamic model is, however, included in Excel in a run-to-steady-state mode where all feed and input parameters are fixed and time steps are progressed until the computed load and discharge stabilises.

This mode is useful for extracting separated ${\displaystyle R_{i}}$ and ${\displaystyle D_{i}}$ functions from steady-state data such as plant surveys or other model calibrations (including the steady-state Perfect Mixing stirred mill model).

The run-to-steady-state dynamic Perfect Mixing stirred mill model may be invoked from the Excel formula bar with the following function call:

=mdUnit_StirredMill_PerfectMixingRiDi(Parameters as Range, Size as Range, MillFeed as Range, OreSG As Range, Appearance as Range, WorkIndexSim as Range, RKnotPositions as Range, RKnotsOrig as Range, Classification as Range, Optional ScalingExponents as Range)

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:

${\displaystyle Parameters={\begin{bmatrix}D{\text{ (m)}}\\H{\text{ (m)}}\\(H_{\rm {b}})_{\rm {Orig}}{\text{ (m)}}\\(D_{\rm {b}})_{\rm {Orig}}{\text{ (mm)}}\\(D_{\rm {s}})_{\rm {Orig}}{\text{ (m)}}\\(N_{\rm {s}})_{\rm {Orig}}{\text{ (rpm)}}\\S_{\rm {Orig}}\\T_{\rm {Orig}}\\(H_{\rm {b}})_{\rm {Sim}}{\text{ (m)}}\\(D_{\rm {b}})_{\rm {Sim}}{\text{ (mm)}}\\(D_{\rm {s}})_{\rm {Sim}}{\text{ (m)}}\\(N_{\rm {s}})_{\rm {Sim}}{\text{ (rpm)}}\\S_{\rm {Sim}}\\T_{\rm {Sim}}\\{\rm {WI}}_{\rm {Orig}}{\text{ (kWh/t)}}\\(Q_{\rm {M,F}})_{\rm {L}}{\text{ (t/h)}}\\\rho _{\rm {L}}{\text{ (t/m}}^{\text{3}}{\text{)}}\\{\text{Classification method}}\\x_{\rm {m}}{\text{ (mm)}}\\{\text{Discharge type}}\\{\text{User overflow volume (m}}^{\text{3}}{\text{)}}\\\end{bmatrix}},\;\;\;\;\;\;Size={\begin{bmatrix}d_{1}{\text{ (mm)}}\\\vdots \\d_{n}{\text{ (mm)}}\\\end{bmatrix}},\;\;\;\;\;\;MillFeed={\begin{bmatrix}(Q_{\rm {M,F}})_{11}{\text{ (t/h)}}&\dots &(Q_{\rm {M,F}})_{1m}{\text{ (t/h)}}\\\vdots &\ddots &\vdots \\(Q_{\rm {M,F}})_{n1}{\text{ (t/h)}}&\dots &(Q_{\rm {M,F}})_{nm}{\text{ (t/h)}}\\\end{bmatrix}},\;\;\;\;\;\;OreSG={\begin{bmatrix}(\rho _{\rm {S}})_{1}{\text{ (t/m}}^{\text{3}}{\text{)}}&\dots &(\rho _{\rm {S}})_{m}{\text{ (t/m}}^{\text{3}}{\text{)}}\\\end{bmatrix}}}$

${\displaystyle Appearance={\begin{bmatrix}{\begin{bmatrix}A_{1}{\text{ (frac)}}\\\vdots \\A_{31}{\text{ (frac)}}\\\end{bmatrix}}_{1}\dots {\begin{bmatrix}A_{1}{\text{ (frac)}}\\\vdots \\A_{31}{\text{ (frac)}}\\\end{bmatrix}}_{m}\end{bmatrix}},\;\;\;\;\;\;{\rm {WI}}_{\rm {Sim}}={\begin{bmatrix}{\rm {WI}}_{1}{\text{ (kWh/t)}}&\dots &{\rm {WI}}_{m}{\text{ (kWh/t)}}\\\end{bmatrix}},\;\;\;\;\;\;R/D^{*}KnotPositions={\begin{bmatrix}d_{1}{\text{ (mm)}}\\\vdots \\d_{k}{\text{ (mm)}}\\\end{bmatrix}},\;\;\;\;\;\;R/D^{*}KnotOrig={\begin{bmatrix}\ln \left({\frac {R}{D^{*}}}\right)_{1}\\\vdots \\\ln \left({\frac {R}{D^{*}}}\right)_{k}\\\end{bmatrix}}}$

${\displaystyle Classification={\begin{cases}{\begin{bmatrix}C_{1}{\text{ (frac)}}\\\vdots \\C_{31}{\text{ (frac)}}\\\end{bmatrix}}&{\mbox{if Classification method}}=0{\mbox{ (User)}}\\x_{\rm {g}}&{\mbox{if Classification method}}=1{\mbox{ (Leung)}}\\\end{cases}}}$

${\displaystyle {\mathit {ScalingExponents}}={\begin{bmatrix}e_{1}\\e_{2}\\e_{3}\\e_{4}\\e_{5}\\e_{6}\\e_{7}\\\end{bmatrix}}^{*}}$

where:

• ${\displaystyle (Q_{\rm {M,F}})_{\rm {L}}}$ is the mass flow feed rate of liquids into the mill (t/h)
• ${\displaystyle \rho _{\rm {B}}}$ is the Specific Gravity or density of the media in the mill (- or t/m³)
• ${\displaystyle \rho _{\rm {L}}}$ is the Specific Gravity or density of liquids in the feed (- or t/m³)
• ${\displaystyle m}$ is the number of ore types
• ${\displaystyle k}$ is the number of breakage rate per discharge rate knots
• ${\displaystyle d_{i}}$ is the size of the square mesh interval that feed mass is retained on (mm)
• ${\displaystyle d_{i+1}<d_{i}<d_{i-1}}$, i.e. descending size order from top size (${\displaystyle d_{1}}$) to sub mesh (${\displaystyle d_{n}=0}$ mm)
• ${\displaystyle Q_{\rm {M,F}}}$ is the mass flow rate of particles in the feed (t/h)
• ${\displaystyle \rho _{\rm {S}}}$ is the Specific Gravity or density of solids (- or t/m³)
• ${\displaystyle {\text{Classification method }}}$ is the method used to defined the classification-by-size to discharge, 0 = User-defined partition or 1 = Leung method
• ${\displaystyle {\text{Discharge type}}}$ is discharge configuration, 0 = Overflow discharge at mill height, 1 = Overflow discharge at user-defined slurry filling volume
• ${\displaystyle {\text{User overflow volume}}}$ is the user-specified slurry filling volume at which overflow commences (if ${\displaystyle {\text{Discharge type}}=1}$) (m³)
• ${\displaystyle ^{*}}$ indicates the ${\displaystyle {\mathit {ScalingExponents}}}$ array is optional, the default values are used if omitted.

Results

The results are displayed in Excel as an array corresponding to the matrix notation below:

${\displaystyle mdUnit\_StirredMill\_PerfectMixing\_RiDi={\begin{bmatrix}{\begin{bmatrix}Q_{\rm {V}}{\text{ (m}}^{\text{3}}{\text{/h)}}\\V_{\rm {Mill}}{\text{ (m}}^{\text{3}}{\text{)}}\\V_{\rm {Media}}\\V_{\rm {Slurry}}\\{\rm {LF}}{\text{ (v/v)}}\\\tau {\text{ (min)}}\\{\text{R/D* factor (frac)}}\\f_{\rm {Ds}}{\text{ (-)}}\\f_{\rm {Hb}}{\text{ (-)}}\\f_{\rm {Ns}}{\text{ (-)}}\\f_{\rm {S}}{\text{ (-)}}\\f_{\rm {T}}{\text{ (-)}}\\f_{\rm {Db}}{\text{ (-)}}\\f_{\rm {WI}}{\text{ (-)}}\\{\text{Iterations}}\\dt{\text{ (s)}}\\d_{\rm {max}}{\text{ (h}}^{\text{-1}}{\text{)}}\\{\text{Ore mass (t)}}\\{\text{Liquid mass (t)}}\\{\text{Ball mass (t)}}\\{\text{Slurry in mill (m}}^{\text{3}}{\text{)}}\\{\text{Max. slurry in charge (m}}^{\text{3}}{\text{)}}\\{\text{Max. slurry in mill (OF) (m}}^{\text{3}}{\text{)}}\\(Q_{\rm {M,P}})_{\rm {L}}{\text{ (t/h)}}\\\end{bmatrix}}&{\begin{array}{cccccccc}{\begin{bmatrix}d_{1}{\text{ (mm)}}\\\vdots \\d_{n}{\text{ (mm)}}\end{bmatrix}}&{\begin{bmatrix}(Q_{\rm {M,P}})_{11}{\text{ (t/h)}}&\dots &(Q_{\rm {M,P}})_{1m}{\text{ (t/h)}}\\\vdots &\ddots &\vdots \\(Q_{\rm {M,P}})_{n1}{\text{ (t/h)}}&\dots &(Q_{\rm {M,P}})_{nm}{\text{ (t/h)}}\\\end{bmatrix}}&{\begin{bmatrix}M_{11}{\text{ (t/h)}}&\dots &M_{1m}{\text{ (t/h)}}\\\vdots &\ddots &\vdots \\M_{n1}{\text{ (t/h)}}&\dots &M_{nm}{\text{ (t/h)}}\\\end{bmatrix}}&{\begin{bmatrix}{\bar {d}}_{1}{\text{ (mm)}}\\\vdots \\{\bar {d}}_{31}{\text{ (mm)}}\\\end{bmatrix}}&{\begin{bmatrix}R_{11}\left({\text{h}}^{\text{-1}}\right)&\dots &R_{1m}\left({\text{h}}^{\text{-1}}\right)\\\vdots &\ddots &\vdots \\R_{31,1}\left({\text{h}}^{\text{-1}}\right)&\dots &R_{31m}\left({\text{h}}^{\text{-1}}\right)\\\end{bmatrix}}&{\begin{bmatrix}D_{1}\left({\text{h}}^{\text{-1}}\right)\\\vdots \\D_{31}\left({\text{h}}^{\text{-1}}\right)\\\end{bmatrix}}&{\begin{bmatrix}C_{1}{\text{ (frac)}}\\\vdots \\C_{31}{\text{ (frac)}}\\\end{bmatrix}}&{\begin{bmatrix}\ln R_{11}&\dots &\ln R_{1m}\\\vdots &\ddots &\vdots \\\ln R_{k1}&\dots &\ln R_{km}\\\end{bmatrix}}\\&&&&&&&\\&&&&&&&{\begin{bmatrix}R_{11}\left({\text{h}}^{\text{-1}}\right)&\dots &R_{1m}\left({\text{h}}^{\text{-1}}\right)\\\vdots &\ddots &\vdots \\R_{k1}\left({\text{h}}^{\text{-1}}\right)&\dots &R_{km}\left({\text{h}}^{\text{-1}}\right)\\\end{bmatrix}}\\&&&&&&&\\&&&&&&&{\begin{bmatrix}(Factor_{\rm {WI}})_{1}&\dots &(Factor_{\rm {WI}})_{m}\end{bmatrix}}\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\&&&&&&\\\end{array}}\end{bmatrix}}}$

where:

• ${\displaystyle {\rm {LF}}}$ is the media load fraction (v/v), defined as the fraction of mill volume occupied by media, including void spaces, i.e. ${\displaystyle {\rm {LF}}=H_{\rm {b}}{\big /}H}$
• ${\displaystyle {\text{R/D* factor}}=D_{i}^{*}/D_{i}}$ is the discharge rate scaling factor
• ${\displaystyle Q_{\rm {M,P}}}$ is the mass flow rate of particles in the mill product (t/h)
• ${\displaystyle {\bar {d}}_{i}}$ is the geometric mean size of the internal mesh series interval that mass is retained on (mm)
• ${\displaystyle {\text{Iterations}}}$ is the number of time steps required to reach steady-state
• ${\displaystyle dt}$ is the size of the discretised time step calculated by the model, ${\displaystyle \Delta t}$ (s)
• ${\displaystyle {\text{Ore mass}}}$ is the total mass of ore in the mill at steady-state (t)
• ${\displaystyle {\text{Liquid mas}}}$ is the mass of liquids in the mill at steady-state (t)
• ${\displaystyle {\text{Ball mass}}}$ is the mass of balls in the mill at steady-state (t)
• ${\displaystyle {\text{Slurry in mill}}}$ is the volume of slurry in the mill at steady-state (m³)
• ${\displaystyle {\text{Max. slurry in charge}}}$ is the maximum volume of slurry that can occupy the charge void space before (m³)
• ${\displaystyle {\text{Max. slurry in mill (OF)}}}$ is the maximum volume of slurry in the mill before overflow commences (m³)
• ${\displaystyle (Q_{\rm {M,P}})_{\rm {L}}}$ is the discharge mass flow rate of liquids from the mill (t/h)
• ${\displaystyle M}$ is the mass of solids in the mill (t)

Example

The images below show the selection of input arrays and output results in the Excel interface.

Figure 4. Example showing the selection of the Parameters (blue frame) array in Excel.

Figure 5. Example showing the selection of the Appearance (pink frame), RKnotPositions (teal frame), RKnotsOrig (blue frame), WorkIndexSim (dark red frame), Classification (Leung, ${\displaystyle x_{\rm {g}}}$) (red frame) arrays in Excel.

Figure 6. Example showing the selection of the Size (red frame), OreSG (green frame) and MillFeed (purple frame) arrays in Excel.

Figure 7. Example showing the outline of the Results (light blue frame) array in Excel.

SysCAD

The SysCAD interface for Dynamic mode is described below. For steady-state, see Stirred Mill (Perfect Mixing).

MD_Mill page

The first tab page in the access window will have this name.

Mill page

The Mill page is used to specify the input parameters for the mill model.

Tag (Long/Short)	Input / Display	Description/Calculated Variables/Options
PerfectMixing
HelpLink		Opens a link to this page using the system default web browser. Note: Internet access is required.
Requirements
NumParallelUnits	Input	The number of parallel, identical units to simulate: Feed is divided by the number of parallel units before being sent to the unit model. Unit model product is multiplied back by the same value and returned to the SysCAD product stream. All unit model result values are shown per parallel unit.
Mode	Steady State	The steady-state Perfect Mixing stirred mill model is used in SysCAD Dynamic simulation mode used instead of the dynamic Perfect Mixing model described here. This approach may be useful when very large SysCAD step sizes are used and steady-state operation can be assumed between each time step.
	Dynamic	The dynamic Perfect Mixing stirred mill model described here is used to determine the mill product size distribution. Different parameters can be used for different solids.
MinSubSteps	Input	The user-specified minimum number of internal models steps taken per SysCAD step.
SubSteps	Display	The actual number of internal models steps taken per SysCAD step. May be affected by breakage/discharge rates or the user-specified MinSubSteps parameter.
DischargeType	Overflow	The maximum slurry volume in the mill before overflowing is calculated by the model.
	Overflow (User)	The maximum slurry volume in the mill before overflowing is specified by the user.
MediaStringsP50	CheckBox	Only visible if the MediaStrings option is checked. Replaces the MediaSize.Sim user defined value with the MediaSize (All) P50 value from the MediaStrings page. The value of MediaSize.Orig should be determined on the same basis for correct scaling of a changed media charge.
Stirred
UserExponents	Checkbox	Indicates whether to use user-defined values for the scaling exponents.
MillDiameter	Input	The inside liner diameter of the simulated mill.
MillHeight	Input	The height of the simulated mill.
MediaHeight	Input	Height of the media charge of the original and simulated mills.
MediaDiameter	Input	Median diameter of the media in the original and simulated mills.
StirrerDiameter	Input	Diameter of the stirrers of the original and simulated mills.
StirrerSpeed	Input	Rotational speed of the stirrers of the original and simulated mills.
StirrerStarts	Input	Number of starts of the (screw) stirrers of the original and simulated mills.
StirrerTurns	Input	Number of turns per start of the (screw) stirrers of the original and simulated mills.
WorkIndex	Input	Bond Ball Work Index of ore in the original mill.
Exponent	Input	Only visible if UserExponents is selected Allows user to specify values of the scaling exponent for each original/simulated parameter pair.
RFunction
NumSplineKnots	Input	Number of spline knots for the ${\displaystyle R_{i}}$ function.
Size	Input	Spline knot size positions.
Ln(R)	Input	Values of ${\displaystyle \ln R}$ at each spline knot position.
Results
MillVolume	Display	Volume inside the mill.
MediaVolume	Display	Volume occupied by the media in the mill, excluding void space.
SlurryVolume	Display	Volume of slurry in the mill, including slurry in media void space and above media charge.
LoadFraction	Display	Volume of media charge, including void space and excluding stirrer volume, as a fraction of mill volume, excluding stirrer volume.
ResidenceTime	Display	Mean residence time of slurry in the mill.

Ore page

This page is used to define the comminution properties of SysCAD species with the size distribution quality in the project.

RiDi page

This page displays the scaling factors and breakage rate per discharge rate for each size interval computed by the Perfect Mixing model.

Tag (Long/Short)	Input / Display	Description/Calculated Variables/Options
Scaling
StirrerDiameter	Display	Value of the stirrer diameter factor for rate scaling.
MediaHeight	Display	Value of the media height factor for rate scaling.
StirrerSpeed	Display	Value of the stirrer speed factor for rate scaling.
StirrerStarts	Display	Value of the stirrer starts factor for rate scaling.
StirrerTurns	Display	Value of the stirrer turns per start factor for rate scaling.
MediaSize	Display	Value of the media size factor for rate scaling.
WorkIndex	Display	Value of the Work Index factor of each ore species for rate scaling.
Rates
Size	Display	Size of each interval in internal mesh series.
MeanSize	Display	Geometric mean size of each interval in internal mesh series.
R	Display	Value of breakage rate, ${\displaystyle R_{i}}$, for each size interval, for each ore species.
C	Display	Value of classification function, ${\displaystyle C_{i}}$, for each size interval.
D	Display	Value of discharge rate, ${\displaystyle D_{i}}$, for each size interval.

Load page

This page displays information about the balls, solids and liquids that currently comprise the mill load.

Content, Sp, Ec, Sz and MSz pages

These pages display the standard SysCAD Material Content, Species Content and Size pages for the current mill load

Power page

This optional page displays the inputs and results for alternative mill power models. The page is only visible if PowerModels is selected on the MD_Mill page.

MediaStrings page

This page displays the inputs and results for grinding mill media string calculations. The page is only visible if MediaStrings is selected on the MD_Mill page.

About page

This page is provides product and licensing information about the Met Dynamics Models SysCAD Add-On.

Tag (Long/Short)	Input / Display	Description/Calculated Variables/Options
About
HelpLink		Opens a link to the Installation and Licensing page using the system default web browser. Note: Internet access is required.
Information		Copies Product and License information to the Windows clipboard.
Product
Name	Display	Met Dynamics software product name
Version	Display	Met Dynamics software product version number.
BuildDate	Display	Build date and time of the Met Dynamics Models SysCAD Add-On.
License
File		This is used to locate a Met Dynamics software license file.
Location	Display	Type of Met Dynamics software license or file name and path of license file.
SiteCode	Display	Unique machine identifier for license authorisation.
ReqdAuth	Display	Authorisation level required, MD-SysCAD Full or MD-SysCAD Runtime.
Status	Display	License status, LICENSE_OK indicates a valid license, other messages report licensing errors.
IssuedTo	Display	Only visible if Met Dynamics license file is used. Name of organisation/seat the license is authorised to.
ExpiryDate	Display	Only visible if Met Dynamics license file is used. License expiry date.
DaysLeft	Display	Only visible if Met Dynamics license file is used. Days left before the license expires.

See also

• Steady-state Perfect Mixing stirred mill model
• Herbst-Fuerstenau mill model
• Stirred Mill (Power, Nitta)
• Stirred Mill (Power, Heath)

References