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Abstract
A computer model has been developed to simulate the distribution behaviors of Ni, Co, Sn, Pb, Zn, As, Sb, Bi, Au and Ag in copper smelting process. The model assumes that the copper smelting furnace is in thermodynamic equilibrium. As many as 21 elements (Cu, S, Fe, Ni, Co, Sn, As, Sb, Bi, Pb, Zn, Au, Ag, O, N, C, H, Ca, Mg, Al, and Si) and 73 compounds are considered. This model accounts for physical entrainment in the melts. The predictions by the present computer model are compared with the known commercial data from Guixi Smelter in China. Horne Smelter in Canada and Naoshima Smelter in Japan. The agreements between the computer predictions and the commercial data are excellent, so that the present computer model can be used to monitor and optimize the actual industrial operations of copper smelting. It is applicable to simulation of almost all copper pyrometallurgical processes.
Keywords
simulate
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distribution behaviors
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copper
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smelting
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computer model
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Pengfu Tan, Chuanfu Zhang.
Computer model of copper smelting process and distribution behaviors of accessory elements.
Journal of Central South University, 1997, 4(1): 36-41 DOI:10.1007/s11771-997-0027-y
| [1] |
ItagakiK. Thermodynamic evaluation of distribution behaviour of VA elements and effect of the use of oxygen in copper smelting. Metallurgical Review of MMIJ, 1986, 3(3): 87-87
|
| [2] |
ChaubalP C. Mathematical modeling of minor-element behavior in flash smelting of copper concentrates and flash converting of copper mattes. Metallurgical Transactions, 1989, 20B(12): 39-39
|
| [3] |
ShimpoR, OgawaO, GotoS. An improved computer program for equilibrium calculation. Metallurgical Transactions, 1993, 24A(8): 1882-1882
|
| [4] |
ShimpoR, WatanabeY, GotoSSohnH Y. An application of equilibrium calculations to the copper smelting operation. Advances in Sulfide Smelting, 1983, Utah, Americal Institute of Mining, Metallurgical and Petroleum Engineers: 295-295
|
| [5] |
NagamoriN, MackeyP J. Thermodynamics of copper matte converting. Metallurgical Transactions, 1978, 9B: 567-567
|
| [6] |
JalkanenH K, HolppaL E KSohnH YAdvances in sulfide smelting, 1983, Utah, Americal Institute of Mining, Metallurgical and Petroleum Engineers: 277-277
|
| [7] |
NagamoriM, MackeyP J. Thermodynamics of copper matte converting. Metallurgical Transactions, 1978, 9B(6): 255-255
|
| [8] |
YazawaA, NakazawaSSohnH Y. Distribution behavior of various elements in copper smelting systems. Advances in Sulfide Smelting, 1983, Utah, Americal Institute of Mining, Metallurgical, Petroleum Engineers: 90-90
|
| [9] |
SinhaS N, NagamoriM. Activities of CoS, FeS in copper mattes and the behavior of cobalt in copper smelting. Metallurgical Transactions, 1982, 13B(9): 461-461
|
| [10] |
SinhaS N, SohnH Y, NagamoriM. Activity of SnS in copper-saturated matte. Metallurgical Transactions, 1984, 15B(9): 595-595
|
| [11] |
SinhaS N, SohnH Y, NagamoriM. Distribution of gold and silver between copper and matte. Metallurgical Transactions, 1985, 16B(3): 53-53
|
| [12] |
TakedaY, IshinataS, YazawaA. Distribution equilibria of minor elements between liquid copper and calcium ferrite slag. Transactions of the Japan Institute of Metals, 1983, 24(7): 518-518
|
| [13] |
MackeyP J. The physical chemistry of copper smelting slags-A review. Canadian Metallurgical Quarterly, 1982, 21(3): 221-221
|
| [14] |
GrimseyE J, LiuX L. The activity coefficient of cobalt oxide in silica-saturated iron silicate slags. Metallurgical Transactions, 1995, 26B(4): 229-229
|
| [15] |
NagamoriM, ErringtonW J, MackeyP J. Thermodynamic simulation model of the Isasmelt process for copper matte. Metallurgical Transactions, 1994, 25B(12): 839-839
|
| [16] |
SeoK W, SohnH Y. Mathematics modeling of sulfide flash smelting process. Metallurgical Transactions, 1991, 22B(12): 791-791
|
| [17] |
NagamoriM, MackeyP J, TarassoffP. Thermodynamics of copper matte converting. Metallurgical Transactions, 1982, 13B(9): 319-319
|
| [18] |
ReddyR G, HealyG W. The solubility of cobalt in Cu2O-CoO-SiO2 slags in equilibrium with liquid Cu-Co alloys. Canadian Metallurgical Quarterly, 1981, 20(2): 135-135
|
| [19] |
WanZhenghua. An outline of operations at the Horne Smelter. Nonferrous Metals Engineering & Research, 1993, 14(4): 18-18(in Chinese)
|
| [20] |
GotoM. High intensity operation at Naoshima Smelter. Journal of Metals, 1986, 12: 43-43
|
