Evaluation of residence time distribution and mineralogical characterization of the biooxidation of sulfide minerals in a continuous stirred tank reactor

Evaluation of residence time distribution and mineralogical characterization of the biooxidation of sulfide minerals in a continuous stirred tank reactor

•The RTD was interpreted using a mathematical model of stirred tanks in parallel.•The oxidation of sulfide and the phases generated through the biooxidation process were evaluated via X-ray diffraction.•The estimated mean residence time for the model was approximately 36% greater than the theoretica...

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Bibliographic Details
Published in:Minerals engineering Vol. 46-47; pp. 128 - 135
Main Authors: Arroyave G., Diana M., Gallego S., Darío, Márquez G., Marco A.
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-06-2013
Subjects:
Biooxidation
CSTR
Jarosite
RTD
Tracer
XRD
CSTR
Biooxidation
RTD
XRD
Tracer
Jarosite
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Summary:•The RTD was interpreted using a mathematical model of stirred tanks in parallel.•The oxidation of sulfide and the phases generated through the biooxidation process were evaluated via X-ray diffraction.•The estimated mean residence time for the model was approximately 36% greater than the theoretical residence time.•Dead zones could increase the likelihood of jarosite precipitations in a CSTR biooxidation. The residence time distribution (RTD) of the liquid phase and the mineralogical characterization of the biooxidation of refractory gold mineral was studied in a continuous stirred tank reactor. The latter was achieved using a native mixed culture of acidophilic mesophiles. The RTD was assessed using a mathematical model of stirred tanks in parallel. The oxidation of sulfide and the phases generated through the biooxidation process were evaluated via X-ray diffraction (XRD).The results indicated that the experimental RTD fit to the model. The reactor has a high tendency to behave as a completely mixed reactor. However, the mixed flow inside the reactor has disturbances such as by-pass and dead zones. The estimated mean residence time for the model was approximately 36% greater than the theoretical residence time. It was probably caused by the delay in the outflow of the tracer due to gas hold-up, foaming at the top and the design of the reactor outlet structure. The XRD outcomes showed that the oxidation of arsenopyrite was greater than that of pyrite. Similarly, the formation of jarosite and brushite was observed. It was concluded that the dead zones could increase the probability of jarosite precipitations.
ISSN:0892-6875
1872-9444
DOI:10.1016/j.mineng.2013.03.012