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Description
This article describes a dynamic implementation of the Perfect Mixing ball 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 ball mill model. For a full description of the steady-state model, see Ball 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:
The dynamic population balance is described mathematically as:[2]
where:
- is the index of the size interval, , is the number of size intervals
- is the mass feed rate of solids in size interval
- is the mass product rate of solids in size interval
- is the mass of solids in the mill load in size interval
- is the breakage rate of solids in the mill load in size interval
- is the rate of discharge from the mill of solids in size interval
- is the Appearance function, the distribution of particle mass arising from the breakage of a parent particle in size interval into progeny of size interval
Unlike the steady-state version, the load component cannot be eliminated from the equation, nor can the and components be combined into a single term. Therefore, the breakage and discharge rates and 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:
where:
- is the load mass of water in the mill
- is the mass feed rate of water into the mill
- is the discharge rate of water from the mill, normally assumed to equal the value of 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). For sufficiently small increments of time , the mass of ore in size interval in the mill at time is:
Or, more succinctly, the change in load mass in a size fraction during a time increment is:
Similarly, for liquids:
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
The breakage function, , is an input parameter for the dynamic Perfect Mixing model, replacing the term appearing in the steady-state version.
The steady-state Perfect Mixing model scaling factors for mill diameter, load fraction, fraction critical speed, work index and ball diameter are assumed to be explicitly related to the breakage rate and are applied to the function here, i.e.:
The scaling factors are defined as:
where:
- is mill diameter (m)
- is load fraction, the load volume as a fraction of mill volume (v/v)
- is the fraction critical speed of the mill (frac)
- is the Bond Ball Work Index of the ore (kWh/t)
- is the ball diameter (mm)
- is the diameter of a particle of size interval (mm)
- is the maximum breakage rate factor which relates ball size and the size at which is maximum, i.e.
- is interpolated for
and the subscript refers to the original mill from which was derived and refers to the mill being simulated (scaled).
The discharge rate scaling factor, , 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]
where:
and:
- is the fraction of load presented to the grate/overflow discharge
- is the classification function, the fraction of particles of size reporting to the mill product
- is the geometric mean size of particles in size interval (mm)
- is the particle size below which all mass in the size interval reports to mill product, i.e. like water
- is the largest particle size which can report to mill product
Appearance function
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. Alternatively, the default Broadbent-Callcott appearance function may be used, which is defined as:[4]
where is the breakage product particle size and is the original particle size.
Internal mesh series
The {{{1}}} mill model is formulated internally with a geometric progression of 31 mesh sizes at intervals. Feed and product size fractions are automatically converted to and from the internal mesh series during model computation. The size intervals allow the appearance function to be specified as a one-dimensional matrix, rather than the two dimensional form defined above, since
when the intervals are so spaced.
Multi-component modelling
The original {{{1}}} model formulation only considered the properties of a single ore type.
This implementation applies different appearance functions and {{{2}}} 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.
The mill, whether grate of overflow discharge configured, may be in one of a number of slurry filling states at any time:
- Empty (balls only, no slurry)
- Charge void space partially filled with slurry
- Charge void space fully filled with slurry and a slurry pool formed at the toe of the tumbling charge
- Charge void space fully filled, slurry pool is overflowing the trunnion of the mill
The slurry filling states states are illustrated visually in Figure 3 below:
Figure 3. Overflow discharge mill slurry filling states, profile view.
The filling states are numbered are in progressive order as a mill is filled from an empty state. A mill may transition between the states in forward or backward direction during dynamic simulation as the feed and milling conditions change.
Discharge flow from a mill will commence from different filling states depending on whether the mill is grate or overflow configured. There is no product from the mill prior to the commencement of discharge flow and hence the discharge rate, , is zero. During this period, the dynamic population balance reduces to a batch mill formulation (with or without feed), as outlined by Whiten (1974):[5]
Overflow discharge mill
Slurry will not discharge from an overflow mill until filling state 4, once the slurry pool level has risen above the trunnion lip. The volumetric discharge rate of pulp from an overflow mill is then, for practical purposes, equal to the instantaneous volumetric feed rate.
The quantity of slurry in the mill at the point of trunnion overflow is determined by the mill dimensions and charge geometry. The method described by Shi (2016) is used to compute the volumetric sum of slurry within the charge void space and slurry pool at the overflow condition.[6]
The model computes the value of 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 an overflow mill.
Grate discharge mill
Slurry will commence discharging from a grate configured mill from step 2, once the slurry level inside the charge exceeds the level of the outermost apertures in the grate. The discharge rate of a grate mill then increases as the level of slurry held-up in the mill increases.
The method of Morrell and Stephenson (1996) is used to compute the volumetric discharge flow rate of slurry for mill filling states 2 and 3:[7]
where
- and are the volumetric discharge rates of slurry through the grinding media zone and slurry pool, respectively (m3/h)
- and are the slurry discharge coefficients for the grinding media zone and slurry pool, respectively
- is the net fractional slurry hold-up in the grinding media interstices (v/v)
- is the net fractional slurry hold-up in the slurry pool (v/v)
- is the open area weighted mean radial position of the grate apertures (m/m)
- is the total open area of grate apertures (m2)
- is the mill diameter (m)
- is the fraction critical speed of the mill (frac)
- is the net fraction of mill volume occupied by slurry (v/v)
- is the maximum net fractional slurry hold-up in the grinding media zone (v/v)
- is the fraction of mill volume occupied by grinding media, including associated interstices (v/v)
- is the dead fraction of mill volume which is occupied by slurry before discharge commences (v/v)
- is gross fraction of mill volume occupied by slurry (v/v)
- is the relative radial position of the outermost grate apertures (m/m)
The model computes the value of to ensure the flow rate of water and solids discharged from the mill matches the flow rate required by the Morrell and Stephenson relations at the current slurry hold-up level.
If the mill continues to fill due to excessive feed rate or insufficient discharge capacity, the slurry level will eventually overflow the trunnion lip (filling state 4). Once this occurs, the overflow discharge method described above is used to determine pulp outflow (i.e. computed such that mill discharge flow rate = mill feed flow rate).
Power draw
The dynamic Perfect Mixing ball mill model computes the volume of slurry in the mill at each time step according to the unsteady-state population balance, water hold-up, breakage and discharge relations described above.
Estimation of the power draw of the mill must then take into account the instantaneous volume of slurry that is either within the charge void space or in the pool of excess slurry outside the charge.
The tumbling mill power draw model proposed by Hilden and Powell (2018) is based on earlier work by Morrell (1996, 2016) and computes the volume of slurry occupying the four areas illustrated in Figure 4:[8][9]
- A. In the grinding media interstices above the slurry pool level
- B. In the grinding media interstices below the slurry pool level
- C. In the annular sector at the toe of the charge
- D. In the circular segment settled across the centre of the mill
Slurry in areas A - C contributes to the power draw of the mill. Slurry in area D is evenly distributed on each side of the vertical centreline of the mill and therefore does not contribute to power draw.
This makes the Hilden and Powell model it a convenient formulation for use by the dynamic Perfect Mixing mill model, which is continuously computing the total volume of slurry in the mill during simulation.
Additional notes
The Leung classification function applies for both grate and overflow discharge mills:[3][10]
- Grate mills are specified according to the aperture dimensions of installed discharge grates.
- For overflow mills, the maximum particle size reporting to product may be an appropriate estimate of if mill contents are not available.
- Alternatively, overflow mills may be simplified and classification effects ignored by setting for all , if preferred.
- A value of 1 mm for may be an adequate choice for both mill discharge configurations.
Excel
The Perfect Mixing ball 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 and functions from steady-state data such as plant surveys or other model calibrations (including the steady-state Perfect Mixing ball mill model).
The run-to-steady-state dynamic Perfect Mixing ball mill model may be invoked from the Excel formula bar with the following function call:
=mdUnit_BallMill_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)
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 () x column () format:
where:
- is the mill (belly) length
- is angle between the cone end surface and the vertical direction (degrees)
- is the diameter of the discharge trunnion (m)
- is the ball charge volume fraction (often ) (v/v)
- is the void fill fraction, the volumetric fraction of grinding media interstitial void space occupied by slurry (v/v)
- is the specific gravity or density of the ball media (excluding void space) (- or t/m3)
- is the mass flow feed rate of liquids into the mill (t/h)
- is the specific gravity or density of liquids in the feed (- or t/m3)
- is the method used to defined the classification-by-size to discharge, 0 = User-defined partition or 1 = Leung method
- is discharge configuration, 0 = Grate discharge, 1 = Overflow discharge at trunnion height, 2 = Overflow discharge at user-defined slurry filling volume
- is the user-specified slurry filling volume at which overflow commences (if ) (m3)
- is the number of size intervals
- is the number of ore types
- is the number of breakage rate per discharge rate knots
- is feed mass flow rate (t/h)
- is Specific Gravity or density (- or t/m3)
Results
The results are displayed in Excel as an array corresponding to the matrix notation below:
where:
- is the flow rate of pulp into the mill (m3/h)
- is the total volume inside the mill, calculated as the sum of a cylinder and two frustums (m3)
- is the rotational rate of the mill (rpm)
- is the number of time steps required to reach steady-state
- is the size of the discretised time step calculated by the model, (s)
- is the total mass of ore in the mill at steady-state (t)
- is the mass of liquids in the mill at steady-state (t)
- is the mass of balls in the mill at steady-state (t)
- is the volume of slurry in the mill at steady-state (m3)
- is the maximum volume of slurry that can occupy the charge void space before forming a slurry pool (m3)
- is the maximum volume of slurry in the mill before trunnion overflow commences (m3)
- is the discharge mass flow rate of liquids from the mill (t/h)
- is product mass flow rate (t/h)
- 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.
SysCAD
The SysCAD interface for Dynamic mode is described below. For steady-state, see Ball Mill (Perfect Mixing).
MD_Mill page
The first tab page in the access window will have this name.
Tag (Long/Short) | Input / Display | Description/Calculated Variables/Options |
---|---|---|
Tag | Display | This name tag may be modified with the change tag option. |
Condition | Display | OK if no errors/warnings, otherwise lists errors/warnings. |
ConditionCount | Display | The current number of errors/warnings. If condition is OK, returns 0. |
GeneralDescription / GenDesc | Display | This is an automatically generated description for the unit. If the user has entered text in the 'EqpDesc' field on the Info tab (see below), this will be displayed here.
If this field is blank, then SysCAD will display the unit class ID. |
Requirements | ||
On | CheckBox | This enables the unit. If this box is not checked, then the material will pass straight through the mill with no change to the size distribution. |
NumParallelUnits | Input | The number of parallel, identical units to simulate:
|
Method | Fixed Discharge | The discharge particle size distribution is user defined. Different distributions can be used for different solids. |
AG/SAG (Variable Rates) | The Variable Rates AG/SAG mill model is used to determine the mill product size distribution. Different parameters can be used for different solids. | |
Rod Mill (Lynch) | The Lynch rod mill model is used to determine the mill product size distribution. Different parameters can be used for different solids. | |
Ball (Perfect Mixing) | The Perfect Mixing ball mill model (steady-state or dynamic) is used to determine the mill product size distribution. Different parameters can be used for different solids. | |
Stirred (Perfect Mixing) | The Perfect Mixing stirred mill model (steady-state or dynamic) is used to determine the mill product size distribution. Different parameters can be used for different solids. | |
Mill (Herbst-Fuerstenau) | The Herbst-Fuerstenau model is used to determine the mill product size distribution. Different parameters can be used for different solids. | |
Options | ||
ShowQFeed | CheckBox | QFeed and associated tab pages (eg Sp) will become visible, showing the properties of the combined feed stream. |
ShowQProd | CheckBox | QProd and associated tab pages (eg Sp) will become visible, showing the properties of the products. |
SizeForPassingFracCalc | Input | Size fraction for % Passing calculation. The size fraction input here will be shown in the Stream Summary section. |
FracForPassingSizeCalc | Input | Fraction passing for Size calculation. The fraction input here will be shown in the Stream Summary section. |
Stream Summary | ||
MassFlow / Qm | Display | The total mass flow in each stream. |
SolidMassFlow / SQm | Display | The Solids mass flow in each stream. |
LiquidMassFlow / LQm | Display | The Liquid mass flow in each stream. |
VolFlow / Qv | Display | The total Volume flow in each stream. |
Temperature / T | Display | The Temperature of each stream. |
Density / Rho | Display | The Density of each stream. |
SolidFrac / Sf | Display | The Solid Fraction in each stream. |
LiquidFrac / Lf | Display | The Liquid Fraction in each stream. |
Passing | Display | The mass fraction passing the user-specified size (in the field SizeForPassingFracCalc) in each stream. |
Passes | Display | The user-specified (in the field FracForPassesSizeCalc) fraction of material in each stream will pass this size fraction. |
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. | |
Mode | Steady State |
|
Dynamic | The dynamic Perfect Mixing ball 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 | Grate | The ball mill is configured with a grate discharge. |
Overflow | The ball mill is configured with an overflow discharge. The maximum slurry volume in the mill before overflowing the trunnion is calculated by the model. | |
Overflow (User) | The ball mill is configured with an overflow discharge. The user specifies the maximum slurry volume before overflow. | |
Ball | ||
MediaStringsP50 | CheckBox |
|
Diameter | Input | The inside liner diameter of the original and simulated ball mills. |
BellyLength | Input | The inside liner belly length of the simulated ball mill, excluding cones. |
ConeAngle | Input | Angle of the feed and discharge end cones, measured as positive displacement from the vertical direction. |
TrunnionDiameter | Input | The inside liner trunnion diameter of the simulated ball mill. |
LoadFrac | Input | The volumetric load fraction of the original and simulated ball mills. |
FracCS | Input | The fraction critical speed of the original and simulated ball mills. |
WorkIndex | Input | Bond Ball Work Index of ore in the original mill. |
BallSize | Input | Characteristic diameter of balls in original and simulated ball mills. |
MaxBreakageRateFactor / K | Input | Parameter relating ball size and the size at which the breakage rate per discharge rate is maximum. |
RFunction | ||
NumSplineKnots | Input | Number of spline knots for the function. |
Size | Input | Spline knot size positions. |
Ln(R) | Input | Values of at each spline knot position. |
Power | ||
BallVolume | Input | Volumetric fraction of mill occupied by balls and voids. |
VoidFillFraction | Input | Volumetric fraction of void space between balls occupied by slurry. |
BallSG | Input | Specific Gravity or density of ball media. |
Results | ||
MillVolume | Display | Volume inside mill, including cones. |
MillSpeed | Display | Rotational speed of simulated mill. |
Ore page
This page is used to define the comminution properties of SysCAD species with the size distribution quality in the project.
Tag (Long/Short) | Input / Display | Description/Calculated Variables/Options |
---|---|---|
Appearance | ||
DefaultAppearance | Sets all species to the the default Broadbent-Callcott Appearance function. | |
OreSpecific | CheckBox |
|
Appearance | Input | User-specified Appearance function data for all species with size distribution property. |
WorkIndex | ||
WorkIndex.Sim | Input | Bond Ball Work Index data for all species with size distribution property. |
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 | ||
Diameter | Display | Value of the mill diameter factor for rate scaling. |
LoadFraction | Display | Value of the load fraction factor for rate scaling. |
FracCS | Display | Value of the fraction critical speed 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, , for each size interval, for each ore species. |
C | Display | Value of classification function, , for each size interval. |
D | Display | Value of discharge rate, , for each size interval. |
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 DLL*Mill page.
Tag (Long/Short) | Input / Display | Description/Calculated Variables/Options |
---|---|---|
Power |
MediaTraj page
This page displays the inputs and results for tumbling mill media trajectory calculations. The page is only visible if MediaTrajectory is selected on the DLL*Mill page.
Overfilling page
This page displays the inputs and results for overflow discharge mill overfilling calculations. The page is only visible if OverfillingIndicator is selected on the DLL*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
References
- ↑ Napier-Munn, T.J., Morrell, S., Morrison, R.D. and Kojovic, T., 1996. Mineral comminution circuits: their operation and optimisation. Julius Kruttschnitt Mineral Research Centre, Indooroopilly, QLD.
- ↑ Valery Jnr, W. and Morrell, S., 1995. The development of a dynamic model for autogenous and semi-autogenous grinding. Minerals engineering, 8(11), pp.1285-1297.
- ↑ 3.0 3.1 Leung, K., Morrison, R.D. and Whiten, W.J., 1987. An Energy Based Ore Specific Model for Autogenous and Semi-autogenous Grinding, Copper 87, Vina del Mar, Vol. 2, pp 71 - 86
- ↑ Gupta, A. and Yan, D.S., 2016. Mineral processing design and operations: an introduction. Elsevier.
- ↑ Whiten, W.J., 1974. A matrix theory of comminution machines. Chemical Engineering Science, 29(2), pp.589-599.
- ↑ Shi, F., 2016. An overfilling indicator for wet overflow ball mills. Minerals Engineering, 95, pp.146-154.
- ↑ Morrell, S. and Stephenson, I., 1996. Slurry discharge capacity of autogenous and semi-autogenous mills and the effect of grate design. International Journal of Mineral Processing, 46(1-2), pp.53-72.
- ↑ Morrell, S., 1996. Power draw of wet tumbling mills and its relationship to charge dynamics. Pt. 1: a continuum approach to mathematical modelling of mill power draw. Transactions of the Institution of Mining and Metallurgy. Section C. Mineral Processing and Extractive Metallurgy, 105.
- ↑ Morrell, S., 2016. Modelling the influence on power draw of the slurry phase in Autogenous (AG), Semi-autogenous (SAG) and ball mills. Minerals Engineering, 89, pp.148-156.
- ↑ Man, Y.T., 2001. Model-based procedure for scale-up of wet, overflow ball mills part I: outline of the methodology. Minerals engineering, 14(10), pp.1237-1246.