Ball Mill (Overfilling): Difference between revisions

Description

This article describes several methods for estimating the maximum volumetric flow capacity of an overflow ball mill, including the Shi (2016) and Arbiter (1991) approaches.^[1][2]

Model theory

Shi method

Figure 1. Overflow discharge tumbling mill profile showing Shi's assumed charge and slurry pool areas.

Shi (2016) estimated the residence time of an overflow ball mill by considering the volume of slurry present in the grinding media interstices and slurry pool.

This was accomplished by adopting Morrell's (1996) simplified charge geometry and calculating the volume of slurry resident in each of the areas A-C in Figure 1:^[3]

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 slurry pool

The total volume of slurry in the mill is therefore the sum of slurry in areas A-C.

Estimating the slurry volume in areas A-C requires definition of the simplified charge geometry and slurry pool level for the mill in question.

Charge position

The simplified charge geometry is defined by three parameters:

• the angular position of the toe of the charge, ${\displaystyle \theta _{\rm {t}}}$ (rad),
• the angular position of the shoulder charge, ${\displaystyle \theta _{\rm {s}}}$ (rad), and
• the radius of the inner charge surface, ${\displaystyle R_{i}}$ (m).

Morrell's equations are used to define the charge position, i.e.^[3]

The position of the toe of the charge is defined as:

${\displaystyle \theta _{\rm {t}}=2.5307\left(1.2796-J_{\rm {t}}\right)\left(1-{\rm {e}}^{-19.42(\phi _{\rm {c}}-\phi )}\right)+{\frac {\pi }{2}}}$

where:

• ${\displaystyle J_{t}}$ is the volumetric fraction of the mill occupied by balls and coarse rock (including void space and interstitial slurry) (v/v)
• ${\displaystyle \phi }$ (frac) is the theoretical fraction critical speed.

The fraction of critical speed at which centrifuging actually occurs, ${\displaystyle \phi _{\rm {c}}}$ (frac), is:

${\displaystyle \phi _{\rm {c}}={\begin{cases}\phi &\phi >0.35(3.364-J_{\rm {t}})\\0.35(3.364-J_{\rm {t}})&\phi \leq 0.35(3.364-J_{\rm {t}})\\\end{cases}}}$

The position of the shoulder of the charge is:

${\displaystyle \theta _{\rm {s}}={\frac {\pi }{2}}-\left(\theta _{\rm {t}}-{\frac {\pi }{2}}\right){\big [}\left(0.336+0.1041\phi \right)+\left(1.54-2.5673\phi \right)J_{\rm {t}}{\big ]}}$

The inner charge surface radius is:

${\displaystyle R_{i}=r_{\rm {m}}\left(1-{\frac {2\pi \beta J_{\rm {t}}}{2\pi +\theta _{\rm {s}}-\theta _{\rm {t}}}}\right)^{0.5}}$

where ${\displaystyle r_{\rm {m}}}$ is the radius of the mill (m), and the fraction of total charge in the active region, ${\displaystyle \beta }$ (frac), is:

${\displaystyle \beta ={\frac {t_{\rm {c}}}{t_{\rm {f}}+t_{\rm {c}}}}}$

The time taken to travel between the toe and shoulder of the charge during one revolution, ${\displaystyle t_{\rm {c}}}$ (s), is:

${\displaystyle t_{\rm {c}}={\frac {2\pi -\theta _{\rm {t}}+\theta _{\rm {s}}}{2\pi {\bar {N}}}}}$

where the mean rotational rate, ${\displaystyle {\bar {N}}}$ (rev/s), is:

${\displaystyle {\bar {N}}\approx {\frac {N_{\rm {m}}}{2}}}$

and ${\displaystyle N_{\rm {m}}}$ is the rotational rate of the mill shell (rev/s).

The time taken to travel between the shoulder and toe of the charge in free flight during one revolution, ${\displaystyle t_{\rm {f}}}$ (s), is:

${\displaystyle t_{\rm {f}}\approx \left({\frac {2{\bar {r}}\left(\sin \theta _{\rm {s}}-\sin \theta _{\rm {t}}\right)}{g}}\right)^{0.5}}$

where the mean radial position ${\displaystyle {\bar {r}}}$ (m), is:

${\displaystyle {\bar {r}}={\frac {r_{\rm {m}}}{2}}\left[1+\left(1-{\frac {2\pi J_{\rm {t}}}{2\pi +\theta _{\rm {s}}-\theta _{\rm {t}}}}\right)^{0.5}\right]}$

Slurry hold-up below pool level

The volume of slurry held up below the pool level in areas B and C, ${\displaystyle V_{1}}$ (m³), is:

${\displaystyle V_{1}=L_{\rm {m}}(S_{\rm {pool}}-S_{\rm {net\,ball}})}$

where:

• ${\displaystyle L_{\rm {m}}}$ is effective mill length (m)
• ${\displaystyle S_{\rm {pool}}}$ is cross-sectional area of the slurry pool (m²)
• ${\displaystyle S_{\rm {net\,ball}}}$ is cross-sectional area occupied by the grinding media, excluding balls, below the slurry pool level(m²)

This implementation of the Shi model computes ${\displaystyle L_{\rm {m}}}$ as an effective mill length from:

${\displaystyle L_{\rm {m}}={\dfrac {V_{\rm {m}}}{\pi {R_{\rm {m}}}^{2}}}}$

where ${\displaystyle V_{\rm {m}}}$ is the volume of the mill (m³) and ${\displaystyle R_{\rm {m}}}$ is the radius of the mill (m).

The volume of the mill is calculated as the sum of a cylinder and two right circular frustums:^[4]

${\displaystyle V_{\rm {m}}=\pi {R_{\rm {m}}}^{2}L+2\cdot {\bigg [}{\dfrac {\pi }{3}}(R_{\rm {m}}-R_{\rm {t}})\cdot \tan \alpha _{\rm {c}}\cdot \left({R_{\rm {m}}}^{2}+R_{\rm {m}}R_{\rm {t}}+{R_{\rm {t}}}^{2}\right){\bigg ]}}$

where:

• ${\displaystyle L}$ is the length of the cylindrical (belly) section of the mill (m)
• ${\displaystyle R_{\rm {t}}}$ is the radius of the discharge trunnion (m)
• ${\displaystyle \alpha _{\rm {c}}}$ is the cone angle, measured as the angular displacement of the cone surface from the vertical direction (rad)

${\displaystyle S_{\rm {pool}}}$ is computed from:

${\displaystyle S_{\rm {pool}}=0.5{R_{\rm {m}}}^{2}(\theta _{\rm {p}}-\sin \theta _{\rm {p}})}$

${\displaystyle \theta _{\rm {p}}=\pi -2\alpha }$

${\displaystyle \alpha =\arcsin \left({\dfrac {R_{\rm {t}}-\Delta h}{R_{\rm {m}}}}\right)}$

where ${\displaystyle R_{\rm {t}}}$ is the radius of the discharge trunnion (m), and ${\displaystyle \Delta h}$ is the height of the slurry pool level over the trunnion lip (m).

The value of ${\displaystyle \Delta h}$ may be estimated as ${\displaystyle 0.67h}$, where ${\displaystyle h}$ is the slurry height above the trunnion level inside the mill (m):^[5]

${\displaystyle h=k_{\mu }\cdot {\frac {1}{0.67}}\left({\frac {2Q}{\pi R_{\rm {t}}g^{0.5}}}\right)^{\frac {2}{3}}}$

and:

• ${\displaystyle k_{\mu }}$ is an empirical coefficient related to the viscidity of the slurry (Morrell suggests ${\displaystyle k_{\mu }\approx 2}$, Shi applies ${\displaystyle k_{\mu }=1}$)
• ${\displaystyle Q}$ is the volumetric discharge rate of pulp from the mill (m³/s)
• ${\displaystyle g}$ is acceleration due to gravity (m/s²)

${\displaystyle S_{\rm {net\,ball}}}$ is computed as:

${\displaystyle S_{\rm {net\,ball}}=0.5\theta _{\rm {b}}(1-\varepsilon _{\rm {d}})({R_{\rm {m}}}^{2}-{R_{\rm {t}}}^{2})}$

${\displaystyle \theta _{\rm {b}}=2\pi -\alpha -\theta _{\rm {t}}}$

where the dynamic charge porosity, ${\displaystyle \varepsilon _{\rm {d}}}$ (v/v), is:

${\displaystyle \varepsilon _{\rm {d}}=0.4+0.228\left[1-\exp \left(-0.315{\dfrac {\phi }{J_{\rm {t}}}}\right)\right]}$

Slurry hold up above pool level

The volume of slurry held up in the grinding media interstices above the slurry pool level in area A, ${\displaystyle V_{2}}$ (m³), is:

${\displaystyle V_{2}=L_{\rm {m}}.\varepsilon _{\rm {d}}.S_{\rm {ball\,above\,pool}}}$

where:

${\displaystyle S_{\rm {ball\,above\,pool}}=0.5(\theta _{\rm {s}}+\alpha )({R_{\rm {m}}}^{2}-{R_{\rm {t}}}^{2})}$

Residence time and overfilling

The total volume of slurry hold up in the mill is ${\displaystyle V_{\rm {total}}=V_{1}+V_{2}}$ (m³).

The residence time of slurry in the mill, ${\displaystyle t_{\rm {Res}}}$ (s), is then:

${\displaystyle t_{\rm {Res}}={\dfrac {V_{\rm {total}}}{Q}}}$

The axial velocity of slurry through the mill, ${\displaystyle v_{\rm {ax}}}$ (m/s), is:

${\displaystyle v_{\rm {ax}}={\dfrac {L_{\rm {m}}}{t_{\rm {Res}}}}}$

Shi suggests the following residence time limits for overflow discharge ball mills (s):

${\displaystyle t_{\rm {Limit}}={\begin{cases}120{\text{ s}}&D_{\rm {m}}<5.9{\text{ m}}\\60{\text{ s}}&D_{\rm {m}}\geq 5.9{\text{ m}}\\\end{cases}}}$

where ${\displaystyle D_{\rm {m}}}$ is the diameter of the mill (m), i.e. ${\displaystyle D_{\rm {m}}=2R_{\rm {m}}}$.

The maximum volumetric flow rate of the mill, ${\displaystyle Q_{\rm {Max}}}$ (m³/s), at the residence time limit ${\displaystyle t_{\rm {Limit}}}$ may be back-calculated using the above relations. However, as the height of slurry above the trunnion lip (${\displaystyle h}$), and hence residence time (${\displaystyle t_{\rm {Res}}}$), is a function of flow rate, no analytical solution is available and a numerical method is required for computation.

Arbiter method

Based on an analysis of industrial ball mills at five operations, Arbiter (1991) postulated that the axial velocity of pulp through a mill should be less than 2.2% of the mill's tangential velocity. The Arbiter Flow Number, ${\displaystyle N_{\rm {q}}}$, is defined as the ratio of axial to tangential velocity and is determined from:

${\displaystyle N_{\rm {q}}={\dfrac {\left({\dfrac {Q}{{\frac {\pi {D_{\rm {m}}}^{2}}{4}}(0.5-0.66J_{\rm {t}})}}\right)}{\pi N_{\rm {m}}D_{\rm {m}}}},\quad N_{\rm {q}}<0.0217}$

where:

• ${\displaystyle Q}$ is the volumetric discharge rate of pulp from the mill (m3/s)
• ${\displaystyle D_{\rm {m}}}$ is the mill diameter (m)
• ${\displaystyle J_{\rm {t}}}$ is the volumetric charge fraction in the mill (v/v)
• ${\displaystyle N_{\rm {m}}}$ is mill rotational speed (rev/min)

The Arbiter Flow Number equation may be rearranged to yield the following relation for the maximum volumetric discharge rate of slurry from a mill prior to overloading, ${\displaystyle Q_{N_{\rm {q}}}}$ (m³/h):

${\displaystyle Q_{N_{\rm {q}}}=0.0217{\dfrac {\pi ^{2}}{4}}{D_{\rm {m}}}^{3}N_{\rm {m}}(0.5-0.66J_{\rm {t}})\cdot 3600}$

Overfilling may be a risk if the actual volumetric flow rate to/from the mill approaches or exceeds ${\displaystyle Q_{N_{\rm {q}}}}$.

Additional notes

Shi estimated the residence times for a database of 121 overflow ball mills. These residence times are presented as cumulative frequency distributions in Figure 2, allowing the performance a given mill to be ranked against the database.

Figure 2. Cumulative frequency distribution of the volume-based residence time of 121 mills in Shi's database (after Shi, 2016).[1]

Arbiter's relations were developed from a limited database of five mills, the largest of which was 5.3 m diameter x 6.4 m length.

Excel

Shi method

The Shi overflow discharge ball mill overfilling model may be invoked from the Excel formula bar with the following function call:

=mdMillOverfilling_Shi(Parameters as Range)

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

The Parameters array and model results are defined below in matrix notation, along with an example image showing the selection of the same arrays in the Excel interface:

${\displaystyle Parameters={\begin{bmatrix}D_{\rm {m}}{\text{ (m)}}\\L{\text{ (m)}}\\R_{\rm {t}}{\text{ (m)}}\\\alpha _{c}{\text{ (degrees)}}\\\phi {\text{ (frac)}}\\J_{\rm {t}}{\text{ (v/v)}}\\Q{\text{ (m}}^{3}{\text{/h)}}\\k_{\mu }\\\end{bmatrix}},\;\;\;\;\;\;mdMillOverfilling\_Shi={\begin{bmatrix}v_{\rm {ax}}{\text{ (m/s)}}\\t_{\rm {Res}}{\text{ (s)}}\\t_{\rm {Limit}}{\text{ (s)}}\\Q_{\rm {Max}}{\text{ (m}}^{3}{\text{/h)}}\\V_{1}{\text{ (m}}^{3}{\text{)}}\\V_{2}{\text{ (m}}^{3}{\text{)}}\\V_{\rm {total}}{\text{ (m}}^{3}{\text{)}}\\\end{bmatrix}}\;\;\;\;\;\;}$

Figure 3. Example showing the selection of the Parameters (blue frame), and Results (light blue frame) arrays in Excel.

Arbiter method

The Arbiter overflow discharge ball mill overfilling model may be invoked from the Excel formula bar with the following function call:

=mdMillOverfilling_Arbiter(Parameters as Range)

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

The Parameters array and model results are defined below in matrix notation, along with an example image showing the selection of the same arrays in the Excel interface:

${\displaystyle Parameters={\begin{bmatrix}D_{\rm {m}}{\text{ (m)}}\\\phi {\text{ (frac)}}\\J_{\rm {t}}{\text{ (v/v)}}\\\end{bmatrix}},\;\;\;\;\;\;mdMillOverfilling\_Arbiter={\begin{bmatrix}Q_{N_{\rm {q}}}{\text{ (m}}^{3}{\text{/h)}}\\\end{bmatrix}}\;\;\;\;\;\;}$

Figure 4. Example showing the selection of the Parameters (blue frame), and Results (light blue frame) arrays in Excel.

SysCAD

The Ball Mill Overfilling Indicator model is an optional calculation for tumbling mill units. If selected, the input and display parameters below are shown.

Tag (Long/Short)	Input / Display	Description/Calculated Variables/Options
Overfilling
HelpLink		Opens a link to this page using the system default web browser. Note: Internet access is required.
Shi
MillDiameter	Input/Display	Diameter of the mill (inside liners).
BellyLength	Input/Display	Length of the cylindrical section (belly) of the mill (inside liners).
TrunnionDiameter	Input/Display	Diameter of the trunnion (inside liners).
ConeAngle	Input/Display	Angular displacement of the cone surface from the vertical direction.
FracCS	Input/Display	Fraction critical speed of the mill.
Jt	Input/Display	Volumetric fraction of the mill occupied by balls and coarse rock (including voids).
ViscidityCoeff	Input	Coefficient of viscidity.
V1	Display	Volume of slurry below slurry pool level.
V2	Display	Volume of slurry above slurry pool level.
V1	Display	Total volume of slurry in charge and pool.
AxialVelocity	Display	Axial velocity of slurry flow through the charge and pool.
tRes	Display	Residence time of slurry in mill.
tLimit	Display	Shi's suggested lower limit of residence time for mill. Based on mill diameter.
Feed.SLQv	Display	Volumetric flow rate of slurry (solids + liquids) in mill feed.
Feed.SLQv.Limit	Display	Estimated volumetric flow rate of slurry (solids + liquids) in mill feed at tLimit.
Overfilled	True/False	Indicates if tRes is less than tLimit, i.e. mill is overfilled.
Arbiter
MillDiameter	Input/Display	Diameter of the mill (inside liners).
FracCS	Input/Display	Fraction critical speed of the mill.
Jt	Input/Display	Volumetric fraction of the mill occupied by balls and coarse rock (including voids).
Feed.SLQv	Display	Volumetric flow rate of slurry (solids + liquids) in mill feed.
Feed.SLQv.NqLimit	Display	Estimated volumetric flow rate of slurry (solids + liquids) at Arbiters critical flow number limit.

See also

• Tumbling Mill (Power, Morrell Continuum)
• Perfect Mixing ball mill model
• Mill (Herbst-Fuerstenau)

References