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Mathematical Modeling and Pilot Test Validation of Nanoparticles Injection in Heavy Hydrocarbon Reservoirs

Valencia, Juan D.; Mejía, Juan M.; Icardi, Matteo; Zabala, Richard

Mathematical Modeling and Pilot Test Validation of Nanoparticles Injection in Heavy Hydrocarbon Reservoirs Thumbnail


Authors

Juan D. Valencia

Juan M. Mejía

Richard Zabala



Abstract

Heavy-oil mobility in reservoir rocks can be improved, using nanotechnology, by reducing the viscosity of the oil and improving the rock wettability to a water-wet condition. Previous pilot studies in Colombian heavy oil fields reported that nanoparticles dispersed in an oleic carrier fluid (diesel) increased oil production rates between 120–150% higher than before the interventions. However, to optimally deploy a massive nanofluid intervention campaign in heavy oil fields, it is valuable to implement simulation tools that can help to understand the role of operational parameters, to design the operations and to monitor the performance. The simulator must account for nanoparticle transport, transfer, and retention dynamics, as well as their impact on viscosity reduction and wettability restoration. In this paper, we developed and solved, numerically, a 3D mathematical model describing the multiphase flow and interaction of the nanoparticles with oil, brine, and rock surface, leading to viscosity reduction and wettability restoration. The model is based on a multiphase pseudo-compositional formulation, coupled with mass balance equations, of nanoparticles dispersed in water, nanoparticles dispersed in oil, and nanoparticles retained on the rock surface. We simulated a pilot test study of a nanofluid stimulation done in a Colombian heavy oil field. The injection, soaking, and production stages were simulated using a 3D single-well formulation of the mathematical model. The comparison of simulation results with the pilot test results shows that the model reproduced the field observations before and after the stimulation. Simulations showed that viscosity reduction during the post-stimulation period is strongly related to the detachment rate of nanoparticles. Simulation indicates that the recovery mechanism of the nanofluid stimulation is initially governed by viscosity reduction and wettability alteration. At latter times, wettability alteration is the main recovery mechanism. The nanoparticles transferred to the residual water promote the wettability alteration to a water wet condition. The model can be used to design field deployments of nanofluid interventions in heavy oil reservoirs.

Citation

Valencia, J. D., Mejía, J. M., Icardi, M., & Zabala, R. (2022). Mathematical Modeling and Pilot Test Validation of Nanoparticles Injection in Heavy Hydrocarbon Reservoirs. Fluids, 7(4), Article 135. https://doi.org/10.3390/fluids7040135

Journal Article Type Article
Acceptance Date Mar 25, 2022
Online Publication Date Apr 12, 2022
Publication Date Apr 1, 2022
Deposit Date Jun 1, 2022
Publicly Available Date Jun 1, 2022
Journal Fluids
Print ISSN 2311-5521
Electronic ISSN 2311-5521
Publisher MDPI
Peer Reviewed Peer Reviewed
Volume 7
Issue 4
Article Number 135
DOI https://doi.org/10.3390/fluids7040135
Keywords Fluid Flow and Transfer Processes; Mechanical Engineering; Condensed Matter Physics
Public URL https://nottingham-repository.worktribe.com/output/7767103
Publisher URL https://www.mdpi.com/2311-5521/7/4/135

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