Difference between revisions of "Template:BarrattEsagEquation"

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(Barratt SAG Specific Energy Equation)
(Barratt SAG Specific Energy Equation)
 
(One intermediate revision by the same user not shown)
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<math></noinclude>{{{E|E_{SAG}}}} = \left [
+
<math></noinclude>{{{E|E_{SAG}}}} = \left [ \left (
 
{{{WiC|Wi_{C} }}} \times \left ( \frac {10}{\sqrt{ {{{Pc|P_{C} }}} }} - \frac {10}{\sqrt{ {{{F80|F_{80} }}} }} \right ) +
 
{{{WiC|Wi_{C} }}} \times \left ( \frac {10}{\sqrt{ {{{Pc|P_{C} }}} }} - \frac {10}{\sqrt{ {{{F80|F_{80} }}} }} \right ) +
 
{{{WiRM|Wi_{RM}}}} \times \left ( \frac {10}{\sqrt{ {{{Pr|P_{R} }}} }} - \frac {10}{\sqrt{ {{{Pc|P_{C} }}} }} \right ) \times EF_4^{RM} +
 
{{{WiRM|Wi_{RM}}}} \times \left ( \frac {10}{\sqrt{ {{{Pr|P_{R} }}} }} - \frac {10}{\sqrt{ {{{Pc|P_{C} }}} }} \right ) \times EF_4^{RM} +
 
{{{WiBM|Wi_{BM}}}} \times \left ( \frac {10}{\sqrt{110} } - \frac {10}{\sqrt{ {{{Pr|P_{R} }}} }} \right ) \times EF_4^{BM}
 
{{{WiBM|Wi_{BM}}}} \times \left ( \frac {10}{\sqrt{110} } - \frac {10}{\sqrt{ {{{Pr|P_{R} }}} }} \right ) \times EF_4^{BM}
\right ] </math><math>\times 1.25
+
\right )\times 1.25
- {{{WiBM|Wi_{BM}}}} \times \left ( \frac {10}{\sqrt{ {110} }} - \frac {10}{\sqrt{ {{{T80|T_{80} }}} }} \right ) <noinclude></math>
+
- {{{WiBM|Wi_{BM}}}} \times \left ( \frac {10}{\sqrt{ {110} }} - \frac {10}{\sqrt{ {{{T80|T_{80} }}} }} \right ) \right ] <noinclude></math>
   
 
See list of pages that use this formula: {{Special:WhatLinksHere/Template:BarrattEsagEquation}}
 
See list of pages that use this formula: {{Special:WhatLinksHere/Template:BarrattEsagEquation}}

Latest revision as of 20:35, 6 November 2012

Barratt SAG Specific Energy Equation

This is a basic equation of the family of Bond/Barratt calculations. It describes specific energy requirement of a SAG (or Autogenous) mill Esag as a function of feed size F80, transfer size T80 and the work index values at three different sizes:

  • WiC: the Bond low-energy impact crushing work index, covers 20 mm to 100 mm size range.
  • WiRM: the Bond rod mill work index, covers 2 mm to 10 mm size range.
  • WiBM: the Bond ball mill work index, less than 2 mm size range.

There are a series of calibration parameters that correspond to the size ranges listed above. It is useful to think of this model as a hypothetical 3-stage crushing — rod mill — ball mill circuit with a calibration adjustment (1.25) for SAG milling.

  • PC is the hypothetical tertiary crusher product size (default=18850 µm)
  • PR is the hypothetical rod mill product size (default=2100 µm)

Three Rowland Efficiency Factor adjustments are required:

  • EF4RM is the oversize feed factor for rod milling, and is a function of the hypothetical crusher product size or the larger of work index for crushing and work index for rod milling.
  • EF4BM is the oversize feed factor for ball milling, and is a function of the hypothetical rod mill product size and the work index for rod milling.


</noinclude>{{{E|E_{SAG}}}} = \left [ \left ( 
 {{{WiC|Wi_{C}  }}} \times \left ( \frac {10}{\sqrt{ {{{Pc|P_{C} }}} }} - \frac {10}{\sqrt{ {{{F80|F_{80} }}} }} \right ) + 
 {{{WiRM|Wi_{RM}}}} \times \left ( \frac {10}{\sqrt{ {{{Pr|P_{R} }}} }} - \frac {10}{\sqrt{ {{{Pc|P_{C} }}} }} \right ) \times EF_4^{RM} + 
 {{{WiBM|Wi_{BM}}}} \times \left ( \frac {10}{\sqrt{110} } - \frac {10}{\sqrt{ {{{Pr|P_{R} }}} }} \right ) \times EF_4^{BM}
\right )\times 1.25 
- {{{WiBM|Wi_{BM}}}} \times \left ( \frac {10}{\sqrt{ {110} }} - \frac {10}{\sqrt{ {{{T80|T_{80} }}} }} \right ) \right ] <noinclude>

See list of pages that use this formula: