Tumbling Mill (Speed): Difference between revisions

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== Model theory ==
== Model theory ==


The theoretical critical speed of a tumbling mill, <math>N_c</math> (rev/min), is defined as:{{King (2012)}}
The theoretical critical speed of a tumbling mill, <math>N_{\rm c}</math> (rev/min), is defined as:{{King (2012)}}


:<math>N_c = \dfrac{60}{2 \pi} \sqrt \dfrac{2g}{D_m}</math>
:<math>N_{\rm c} = \dfrac{60}{2 \pi} \sqrt \dfrac{2g}{D_{\rm m}}</math>


where <math>D_m</math> is the mill diameter ''inside liners'' (m) and <math>g</math> is acceleration due to gravity (m/s<sup>2</sup>).
where <math>D_{\rm m}</math> is the mill diameter ''inside liners'' (m) and <math>g</math> is acceleration due to gravity (m/s<sup>2</sup>).


Therefore, the fraction critical speed, <math>\phi</math> (frac), given a rotational mill speed, <math>N_m</math> (rev/min), is computed as:
Therefore, the fraction critical speed, <math>\phi</math> (frac), given a rotational mill speed, <math>N_{\rm m}</math> (rev/min), is computed as:


:<math>\phi = \dfrac{2 \pi N_m}{60}\sqrt{\dfrac{D_m}{2g}} </math>
:<math>\phi = \dfrac{2 \pi N_{\rm m}}{60}\sqrt{\dfrac{D_{\rm m}}{2g}} </math>


and the rotational mill speed given a fraction critical speed is:
and the rotational mill speed given a fraction critical speed is:


:<math>N_m = \dfrac{60 \phi}{2 \pi}\sqrt{\dfrac{2g}{D_m}} </math>
:<math>N_{\rm m} = \dfrac{60 \phi}{2 \pi}\sqrt{\dfrac{2g}{D_{\rm m}}} </math>


== Excel ==
== Excel ==
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|-
|-
|style="vertical-align:top;padding: 20px" |
|style="vertical-align:top;padding: 20px" |
<math>millDiameter = D_m\text{ (m)}</math><br>
<math>millDiameter = \big [ D_{\rm m}\text{ (m)} \big ]</math><br>
<math>millRPM= N_m\text{ (rpm)}</math><br>
<math>millRPM= \big [ N_{\rm m}\text{ (rpm)} \big ]</math><br>
<math>mdMillSpeed\_FracCS = \phi\text{ (frac)}</math>
<math>mdMillSpeed\_FracCS = \big [ \phi\text{ (frac)} \big ]</math>
| style="padding: 20px" | [[File:TumblingMillSpeed1.png|left|frame|Figure 1. Example showing the selection of the '''millDiameter''' (blue frame), '''millRPM''' (red frame) and '''Results''' (dark green frame) cells in Excel.]]
| style="padding: 20px" | [[File:TumblingMillSpeed1.png|left|frame|Figure 1. Example showing the selection of the '''millDiameter''' (blue frame), '''millRPM''' (red frame) and '''Results''' (dark green frame) cells in Excel.]]
|}
|}
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<syntaxhighlight lang="vb">=mdMillSpeed_RPM(millDiameter As Double, fracCriticalSpeed as Double)</syntaxhighlight>
<syntaxhighlight lang="vb">=mdMillSpeed_RPM(millDiameter As Double, fracCriticalSpeed as Double)</syntaxhighlight>
{{Excel (Text, Help, No Arguments)}}


The ''millDiameter'', ''fracCriticalSpeed '' and function results are defined for the fraction critical speed function below in matrix notation, along with example images showing the selection of the same cells in the Excel interface:
The ''millDiameter'', ''fracCriticalSpeed '' and function results are defined for the fraction critical speed function below in matrix notation, along with example images showing the selection of the same cells in the Excel interface:
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|-
|-
|style="vertical-align:top;padding: 20px" |
|style="vertical-align:top;padding: 20px" |
<math>millDiameter = D_m\text{ (m)}</math><br>
<math>millDiameter = \big [ D_{\rm m}\text{ (m)} \big ]</math><br>
<math>fracCriticalSpeed = \phi\text{ (frac)}</math><br>
<math>fracCriticalSpeed = \big [ \phi\text{ (frac)} \big ]</math><br>
<math>mdMillSpeed\_RPM = N_m\text{ (rpm)}</math>
<math>mdMillSpeed\_RPM = \big [ N_{\rm m}\text{ (rpm)} \big ]</math>
| style="padding: 20px" | [[File:TumblingMillSpeed2.png|left|frame|Figure 2. Example showing the selection of the '''millDiameter''' (blue frame), '''fracCriticalSpeed ''' (red frame) and '''Results''' (dark green frame) cells in Excel.]]
| style="padding: 20px" | [[File:TumblingMillSpeed2.png|left|frame|Figure 2. Example showing the selection of the '''millDiameter''' (blue frame), '''fracCriticalSpeed ''' (red frame) and '''Results''' (dark green frame) cells in Excel.]]
|}
|}
{{Excel (Text, Help, No Arguments)}}


== See also ==
== See also ==

Latest revision as of 04:42, 19 May 2023

Description

This article describes mathematical methods for converting between the rotational and fraction critical speeds of a tumbling mill.

The critical speed of a horizontal tumbling mill is defined as the minimum speed at which a single element (ball, rod, rock etc.) will remain in contact with the mill wall for a full rotation. The critical speed is therefore a function of mill diameter, rotational speed and the force of gravity.

Tumbling mill speed is frequently referred to as the fraction of critical speed the mill is operating at.

The fraction critical speed of a mill has particular relevance to the mathematical modelling of grinding product size, power draw, and other properties.

Model theory

The theoretical critical speed of a tumbling mill, (rev/min), is defined as:[1]

where is the mill diameter inside liners (m) and is acceleration due to gravity (m/s2).

Therefore, the fraction critical speed, (frac), given a rotational mill speed, (rev/min), is computed as:

and the rotational mill speed given a fraction critical speed is:

Excel

The fraction critical speed of a tumbling mill may be computed from the Excel formula bar with the following function call:

=mdMillSpeed_FracCS(millDiameter As Double, millRPM as Double)

The millDiameter, millRPM and function results are defined for the fraction critical speed function below in matrix notation, along with example images showing the selection of the same cells in the Excel interface:



Figure 1. Example showing the selection of the millDiameter (blue frame), millRPM (red frame) and Results (dark green frame) cells in Excel.

The rotational speed of a tumbling mill may be computed from the Excel formula bar with the following function call:

=mdMillSpeed_RPM(millDiameter As Double, fracCriticalSpeed as Double)

The millDiameter, fracCriticalSpeed and function results are defined for the fraction critical speed function below in matrix notation, along with example images showing the selection of the same cells in the Excel interface:



Figure 2. Example showing the selection of the millDiameter (blue frame), fracCriticalSpeed (red frame) and Results (dark green frame) cells in Excel.

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

See also

References

  1. King, R.P., 2012. Modeling and Simulation of Mineral Processing Systems. Elsevier.