Use of mesophilic and thermophilic bacteria for the improvement of copper extraction from a low-grade ore 被引量：3

Use of mesophilic and thermophilic bacteria for the improvement of copper extraction from a low-grade ore

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摘要 Bioleaching was examined for copper extraction from a low grade ore using mesophilic and moderate thermophilic bacteria. Five equal size columns were used for the leaching of the ore. Sulfuric acid solution with a flow rate of 3.12 L·m-2·h-1 and pH 1.5 passed through each column continuously for 90 d. In the first and the second column, bioleaching was performed without agglomeration of the ore and on the agglomerated ore, respectively. 28wt% of the copper was extracted in the first column after 40 d, while this figure was 38wt% in the second column. After 90 d, however, the overall extractions were almost the same for both of them. Bioleaching with mesophilic bacteria was performed in the third column without agglomeration of the ore and in the fourth column on the agglomerated ore. After 40 d, copper extractions in the third and the fourth columns were 62wt% and 70wt%, respectively. Copper extractions were 75wt% for both the columns after 90 d. For the last column, bioleaching was performed with moderate thermophilic bacteria and agglomerated ore. Copper extractions were 80wt% and 85wt% after 40 and 90 d, respectively. It was concluded that crushing and agglomeration of the ore using bacteria could enhance the copper extraction considerably. Bioleaching was examined for copper extraction from a low grade ore using mesophilic and moderate thermophilic bacteria. Five equal size columns were used for the leaching of the ore. Sulfuric acid solution with a flow rate of 3.12 L·m-2·h-1 and pH 1.5 passed through each column continuously for 90 d. In the first and the second column, bioleaching was performed without agglomeration of the ore and on the agglomerated ore, respectively. 28wt% of the copper was extracted in the first column after 40 d, while this figure was 38wt% in the second column. After 90 d, however, the overall extractions were almost the same for both of them. Bioleaching with mesophilic bacteria was performed in the third column without agglomeration of the ore and in the fourth column on the agglomerated ore. After 40 d, copper extractions in the third and the fourth columns were 62wt% and 70wt%, respectively. Copper extractions were 75wt% for both the columns after 90 d. For the last column, bioleaching was performed with moderate thermophilic bacteria and agglomerated ore. Copper extractions were 80wt% and 85wt% after 40 and 90 d, respectively. It was concluded that crushing and agglomeration of the ore using bacteria could enhance the copper extraction considerably.

作者 E.Darezereshki M.Schaffie M.Lotfalian S.A.Seiedbaghery M. Ranjbar

机构地区 Department of Mineral Processing Engineering Energy and Environmental Engineering Research Center (EERC) Department of Chemical Engineering Industrial Mining Research Center (IMRC) Hydrometallurgy Research Unit

出处《International Journal of Minerals,Metallurgy and Materials》 SCIE EI CAS CSCD 2011年第2期138-143,共6页 矿物冶金与材料学报（英文版）

关键词 BIOLEACHING mesophilic bacteria thermopilic bacteria COPPER EXTRACTION agglomeration. bioleaching mesophilic bacteria thermopilic bacteria copper extraction agglomeration.

分类号 TD84 [矿业工程—煤矿开采]

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参考文献15

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International Journal of Minerals,Metallurgy and Materials

2011年第2期

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Use of mesophilic and thermophilic bacteria for the improvement of copper extraction from a low-grade ore 被引量：3

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