Low Grade Copper Sulfide Ore Bioleaching in a New Bioreactor

Rosa Elva Rivera-Santillán; Felipe Patricio-Ramírez; Irvin Olvera-Pérez

doi:10.4028/www.scientific.net/AMR.825.410

Paper Titles

Impact of the Hydraulic Retention Time on the Performance of a Sulfidogenic Bioreactor
p.392

Investigation of Bioleaching of a Low Grade Nickel-Cobalt-Copper Sulfide Ore with High Magnesium as Olivine and Serpentine from Lao
p.396

Investigation of the Effect of pH Operating Conditions on Bioleaching of Low-Grade Chalcopyrite in Column Reactors
p.401

Isolation and Characterization of Actinomycetes from Acidic Cultures of Ores and Concentrates
p.406

Low Grade Copper Sulfide Ore Bioleaching in a New Bioreactor
p.410

Minimum Aeration in Acidithiobacillus ferrooxidans Cultures Required to Maintain Substrate Oxidation without Oxygen Limitation
p.414

Molybdenite Bioleaching by Thermophilic Bacteria in a RELVA-ARBP Bioreactor
p.418

Potassium Extraction from Biotite by Penicillium and Aspergillus
p.423

Pretreatment of Refractory Gold Ores Using Cell-Free Extracts of P. chrysosporium: A Preliminary Study
p.427

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 825Low Grade Copper Sulfide Ore Bioleaching in a New...

Low Grade Copper Sulfide Ore Bioleaching in a New Bioreactor

Abstract:

Although the biological techniques application into sulfide minerals leaching to obtain valuable metals is an important technological advance, the disadvantage of relatively slow kinetics bio-oxidation still limits its commercial application. However, it stimulates the research for constant improvement. Microorganisms are capable of performing their intended role with great efficiency under optimal conditions. Bioreactor design seeks to maintain certain environmental conditions that favour efficient microbial growth as pH, temperature, oxygen and carbon dioxide dissolution, stirring speed, etc. In an aerobic process such as bioleaching the optimum oxygen transference is extremely difficult to be achieved, because little oxygen dissolves in water. Furthermore the oxygen transference usually is facilitated by agitation, which is also required to mix the nutrients and maintain homogeneous solution, this transference is limited by the agitation speed because of the high power consumption, and the damage that undergoes the microorganisms submitted to excessive shear. In order to improve bio oxidation kinetics, in this paper we designed a new bioreactor, which combines elements of the stirred tank and airlift reactor, and introduces new elements, to their effective use in biohydrometallurgy. A new bio-reactor called RELBA was designed and build-up in the UNAM laboratories. It controls dissolved O₂ among other parameters and it prevents shear. Bioleaching tests of the ore, containing 0.135% Cu and 3.07% Fe, were performed in the orbital incubator and in the RELBA bio-reactor to 35°C using a mixed strain of Acidithiobacillus caldus, Acidihiobacillus thiooxidans and Leptospirillum ferriphilum, which confirm the advantages of the new bioleaching reactor.

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Periodical:

Advanced Materials Research (Volume 825)

Pages:

410-413

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.825.410

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Online since:

October 2013

Authors:

Rosa Elva Rivera-Santillán, Felipe Patricio-Ramírez, Irvin Olvera-Pérez

Keywords:

Copper Bioleaching, Hydrometallurgical Bio-Reactor, Low Grade Ore, Sulfide

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