Simulation of the inhibition of microbial sulfate reduction in a two-compartment upflow bioreactor subjected to molybdate injection

Souring of oil fields during secondary oil recovery by water injection occurs mainly due to the action of sulfate-reducing bacteria (SRB) adhered to the rock surface in the vicinity of injection wells. Upflow packed-bed bioreactors have been used in petroleum microbiology because of its similarity t...

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Bibliographic Details
Published in:Bioprocess and biosystems engineering 2016-08, Vol.39 (8), p.1201-1211
Main Authors: de Jesus, E. B., de Andrade Lima, L. R. P.
Format: Article
Language:English
Subjects:
Bacteria
Bioengineering
Bioreactors
Biotechnology
Chemistry
Chemistry and Materials Science
Environmental Engineering/Biotechnology
Fluid mechanics
Food Science
Hydrodynamics
Industrial and Production Engineering
Industrial Chemistry/Chemical Engineering
Injection
Injection wells
Membrane reactors
Microbiology
Models, Theoretical
Molybdenum - chemistry
Oil and gas fields
Oil recovery
Oil reservoirs
Original Paper
Oxidation-Reduction
Secondary oil recovery
Sulfate reduction
Sulfates
Sulfates - metabolism
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Summary:Souring of oil fields during secondary oil recovery by water injection occurs mainly due to the action of sulfate-reducing bacteria (SRB) adhered to the rock surface in the vicinity of injection wells. Upflow packed-bed bioreactors have been used in petroleum microbiology because of its similarity to the oil field near the injection wells or production. However, these reactors do not realistically describe the regions near the injection wells, which are characterized by the presence of a saturated zone and a void region close to the well. In this study, the hydrodynamics of the two-compartment packing-free/packed-bed pilot bioreactor that mimics an oil reservoir was studied. The packed-free compartment was modeled using a continuous stirred tank model with mass exchange between active and stagnant zones, whereas the packed-bed compartment was modeled using a piston-dispersion-exchange model. The proposed model adequately represents the hydrodynamic of the packed-free/packed-bed bioreactor while the simulations provide important information about the characteristics of the residence time distribution (RTD) curves for different sets of model parameters. Simulations were performed to represent the control of the sulfate-reducing bacteria activity in the bioreactor with the use of molybdate in different scenarios. The simulations show that increased amounts of molybdate cause an effective inhibition of the souring sulfate-reducing bacteria activity.
ISSN:1615-7591
1615-7605
DOI:10.1007/s00449-016-1598-5