Difference between revisions of "Bibliography: Benchmarking"
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** Diameter inside shell = 10.970 m (36 ft) |
** Diameter inside shell = 10.970 m (36 ft) |
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** Diameter inside liners = 10.797 m (35.42 ft, 3.5 inch effective liner thickness) |
** Diameter inside liners = 10.797 m (35.42 ft, 3.5 inch effective liner thickness) |
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− | ** Belly length inside liners (EGL) = 4.417 m |
+ | ** Belly length inside liners (EGL) = 4.417 m (14.5 ft) |
** Centre-line length = 6.920 m |
** Centre-line length = 6.920 m |
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Table 4 presents results of several SAG surveys at different speed and load conditions. The survey measured motor input power. Drives are assumed to have an efficiency of 0.96 and pinion efficiency of 0.985, so the model shell power draw is converted to motor input power by dividing by 0.9456. The predicted power draw of '''Example''' project sample circuit number 7 (Fimiston) using sample '''MLE''', based on the KCGM paper published by Campbell, J. et al; 1998 AusIMM Annual Conference. |
Table 4 presents results of several SAG surveys at different speed and load conditions. The survey measured motor input power. Drives are assumed to have an efficiency of 0.96 and pinion efficiency of 0.985, so the model shell power draw is converted to motor input power by dividing by 0.9456. The predicted power draw of '''Example''' project sample circuit number 7 (Fimiston) using sample '''MLE''', based on the KCGM paper published by Campbell, J. et al; 1998 AusIMM Annual Conference. |
Revision as of 05:45, 11 November 2012
Contents
Bibliography: Benchmarking of models
The following list of references show data useful for benchmarking against the different models.
Benchmarking: Circuit Specific Energy Consumption
Benchmarking: Mill Power Draw
- Nelson, M; Valery, W; Morrell, S, Performance Characteristics and Optimisation of the Fimiston (KCGM) SAG Mill Circuit, Page 233 - 248, SAG 1996 Conference, Vancouver, Canada.
- Diameter inside shell = 10.970 m (36 ft)
- Diameter inside liners = 10.797 m (35.42 ft, 3.5 inch effective liner thickness)
- Belly length inside liners (EGL) = 4.417 m (14.5 ft)
- Centre-line length = 6.920 m
Table 4 presents results of several SAG surveys at different speed and load conditions. The survey measured motor input power. Drives are assumed to have an efficiency of 0.96 and pinion efficiency of 0.985, so the model shell power draw is converted to motor input power by dividing by 0.9456. The predicted power draw of Example project sample circuit number 7 (Fimiston) using sample MLE, based on the KCGM paper published by Campbell, J. et al; 1998 AusIMM Annual Conference.
Survey | Survey Power, kW at input |
Mill speed, %critical |
Ball load, %v/v |
Total load, %v/v |
Pulp %solids, w/w |
Morrell SAG Model, kW at input / shell |
Loveday/Baratt Model, kW at input / shell |
---|---|---|---|---|---|---|---|
Survey 1 | 9,255 | 72.5 | 13 | 21.6 | 65.9 | 9,268 / 8,764 | 10,372 / 9,808 |
Survey 2 | 10,374 | 77 | 13 | 25.2 | 63.3 | 10,481 / 9,911 | 11,238 / 10,636 |
Survey 3 | 8,395 | 75 | 15 | 16.1 | 70 | 9,193 / 8,693 | 10,818 / 10,230 |
Survey 4 | 8,299 | 78 | 11.5 | 13.5 | 60 | 7,766 / 7,344 | can't do |
Survey 5 | 10,976 | 80 | 11.5 | 22.2 | 60 | 9,877 / 9,340 | 10,322 / 9,760 |
Survey 6 | 8,616 | 74 | 11.5 | 13.6 | 63 | 7,394 / 6,992 | can't do |
Survey 7 | 11,684 | 82 | 14 | 20 | 75 | 10,782 / 10,195 | 11,037 / 10,437 |
Survey 8 | 11,610 | 78 | 13 | 28.6 | 75 | 11,415 / 10,794 | 11,125 / 10,520 |
Survey 9 | 11,571 | 78 | 13 | 25.8 | 75 | 10,990 / 10,392 | 11,668 / 11,033 |
Survey 10 | 9,408 | 80 | 12 | 19 | 75 | 9,655 / 9,130 | 10,309 / 9,749 |
- The overall average difference between the Morrell model motor input predictions and the measurements are 3.4%, and range from -9.1% to 15.3%.
- The overall average difference between the Loveday/Barratt model motor input predictions and the measurements are -4.8%, and range from -25.2% to 6.1%.
The SAG mill belly length reported can be achieved with a 16.5 degree head angle and 2.47 m trunnion diameter. The ball mill belly length can be achieved with a 18 degree head angle and 1.9 m trunnion diameter.
Historic & Other Interesting Benchmarking
- Myers, J.F., Michaelson, S.D., Bond, F.C., Rod Milling—Plant and Laboratory Data, Technical Publication No. 2175, American Institute of Mining and Metallurgical Engineers, 1947. [1]