Comparison of the Bioleaching and Chemical Leaching of Cobaltiferous Ores

doi:10.12068/j.issn.1005-3026.2013.11.021

Abstract

Abstract: The cobaltiferous ores were studied by the process mineralogy for their main composition， ore particle size distribution， contents of primary elements and mineral dissemination characteristics. The results showed that the main content of the sulfide ores was carrollite that most of them were in monomer form， while a part of them were intergrowth with other ores. The copper ores were composed of chalcopyrite， bornite， chalcocite， covellite. The ferric sulfide is pyrite primarily. The cobaltiferous ores were comprised of 163% cobalt， 105% copper， 1500% sulfur and 124% iron. Shaking flask experiments were used to test the leaching efficiency of the cobaltiferous ores using ZY101 bacteria which was cultured with good anticobalt properties in the lab. The results showed that the cobalt bioleaching efficiency by bioleaching was 8571% which was 6326% higher than that by chemical leaching with high iron solution. So it was more suitable that recovery of cobalt by bioleaching than by chemical leaching， and ZY101 was favored for cobalt leaching because of its high leaching efficiency and cobalt tolerance.

Key words: cobaltiferous ores, process mineralogy, carrollite, bioleaching, chemical leaching

CLC Number:

TF18

LIU Wei， YANG Hongying， LIU Yuanyuan， LUO Wenjie. Comparison of the Bioleaching and Chemical Leaching of Cobaltiferous Ores[J]. Journal of Northeastern University(Natural Science), 2013, 34(11): 1606-1609.

References

[1] 潘彤.我国钴矿矿产资源及其成矿作用［J］.矿产与地质，2003，17(4):516/518.(Pan Tong.Cobalt resources and its mineralization in China［J］.Mineral Resources and Geology，2003，17(4):516/518.)
[2] Behera S K，Panda P P，Singh S，et al.Study on reaction mechanism of bioleaching of nickel and cobalt from lateritic chromite overburdens［J］.International Biodeterioration & Biodegradation，2011，65:1035/1042.(下转第1614页)(上接第1609页)
[3] (d′Hugues P，Cezac P，Cabral T，et al.Bioleaching of cobaltiferous pyrite:a continuous laboratoryscale study at high solids concentration［J］.Minerals Engineering，1997，10(5):507/527.
[4] 温建康，阮仁满.高砷硫低镍钴硫化矿浸矿菌的选育与生物浸出研究［J］.稀有金属，2007，31(4):537/542.(Wen Jiankang，Ruan Renman.Selection of bioleaching bacteria and bioleaching of high arsenic/sulfur，lowgrade nickel/cobalt sulfide ore［J］.Chinese Journal of Rare Metals，2007，31(4):537/542.)
[5] Yang C R，Qin W Q，Lai S S，et al.Bioleaching of a low grade nickelcoppercobalt sulfide ore［J］.Hydrometallurgy，2011，106:32/37.
[6] Yang H Y，Wang S H，Song X L，et al.Gold occurrence of Jiaojia gold mine in Shandong province［J］.Transactions of Nonferrous Metals Society of China，2011，21:2072/2077.
[7] Gautier V，Escobar B，Vargas T.Cooperative action of attached and planktonic cells during bioleaching of chalcopyrite with Sulfolobus metallicus at 70℃［J］.Hydrometallurgy，2008，94(1/4):121/126.
[8] Tributsch H.Direct versus indirect bioleaching［J］.Hydrometallurgy，2001，59:177/185.
[9] Crundwell F K.How do bacteria interact with minerals?［J］.Hydrometallurgy，2003，71:75/81.
[10] Hansford G S，Vargas T.Chemical and electrochemical basis of bioleaching processes［J］.Hydrometallurgy，2001，59(2/3):135/145.

[1]	GONG Ao， XU Zhi-feng， WANG Rui-xiang， TIAN Lei. Study on Process Mineralogy of Typical Sphalerite Ore Pressure Leaching High Sulfur Residues [J]. Journal of Northeastern University(Natural Science), 2022, 43(10): 1430-1437.
[2]	YU Hong-dong， WANG Li-na， QU Jing-kui， QI Tao. Process Mineralogical Characteristics and Ore Value of Typical Vanadium Titanium Magnetite in China [J]. Journal of Northeastern University Natural Science, 2020, 41(2): 275-281.
[3]	CHEN Qiao， TONG Lin-lin， CHEN Gui-min， YANG Hong-ying. Process Mineralogy of Baolun Gold Mine in Hainan Province [J]. Journal of Northeastern University Natural Science, 2019, 40(9): 1268-1272.
[4]	LIU Xiao， GAO Peng， HAN Yue-xin， YING Ping. Study on Process Mineralogy of a High-Iron Red Mud from Shandong Province [J]. Journal of Northeastern University Natural Science, 2019, 40(11): 1611-1616.
[5]	JIANG Liang-you， WEI De-zhou， LIU Kai-kai， ZHANG Hao. Kinetics of Bioleaching for Copper Sulfide Ore with Different Grade [J]. Journal of Northeastern University Natural Science, 2019, 40(10): 1491-1495.
[6]	DONG Zai-zheng， GAO Peng， ZHANG Shu-min， HAN Yue-xin. Process Mineralogy of Gold Ore in Zaozigou Gold Mine， Gansu Province [J]. Journal of Northeastern University:Natural Science, 2017, 38(5): 711-715.
[7]	ZHANG Rui-yang， WEI De-zhou， LIU Wen-gang， GAO Shu-ling. Effects of Triton X-100 on Oxidative Activity of Acidithiobacillus ferrooxidans and on Chalcopyrite Bioleaching [J]. Journal of Northeastern University Natural Science, 2016, 37(6): 861-865.
[8]	LU Tao， WEI De-zhou， ZHANG Rui-yang， ZHUO Jian-ying. Identification and Bioleaching Capacity of an Acidithiobacillus Ferrooxidan [J]. Journal of Northeastern University Natural Science, 2016, 37(1): 89-93.
[9]	LIU San-ping， CHANG Yong-feng， LU Dian-kun， JIANG Kai-xi. Magnetic Separation and Enrichment of Rough Chromite Concentrate from the Ramu Laterite Project [J]. Journal of Northeastern University Natural Science, 2015, 36(7): 976-980.
[10]	LIU Wei， YANG Hong-ying， TONG Lin-lin， JIN Zhe-nan. Catalytic Effects of Surfactants on the Cobalt Ore Bioleaching [J]. Journal of Northeastern University Natural Science, 2015, 36(6): 814-818.
[11]	LI Haijun， YANG Hongying， CHEN Guobao， LUO Wenjie. Separation and Recovery of Copper from Bioleaching Solution of LowGrade Carrollite [J]. Journal of Northeastern University Natural Science, 2014, 35(3): 391-395.
[12]	SONG Yan， YANG Hong-ying， TONG Lin-lin. Effects of Surfactant Tween 80 on the Bio-Leaching of Cobalt Concentrate [J]. Journal of Northeastern University Natural Science, 2014, 35(12): 1750-1753.