Simulation of water-based nanofluids injection into oil reservoirs using the streamline method
Subject Areas : Applications of Nanostructures
Narges Milaninasab
1
,
Behzad Vaferi
2
1 - Department of Chemical Engineering, Shiraz Branch, Islamic Azad University, Shiraz, Iran
2 - Department of Chemical Engineering, Shiraz Branch, Islamic Azad University, Shiraz, Iran
Keywords: Simulation, Enhanced oil recovery, Nanofluid injection, Streamline method,
Abstract :
The main goal of all reservoir simulators is to predict the flow performance and oil recovery factor. Most commercial simulators solve the equations governing reservoir behavior with the finite difference approach. To solve the three-dimensional equations of flow in a porous media with the finite difference method, the grid dimension has an effect on the simulation results (i.e., divergence). In addition, the simulation of complex reservoirs with a large number of network blocks needs a long computational time. In order to eliminate the effect of block size and increase the speed of simulation, the streamline method has been proposed, which is widely used in the management of hydrocarbon reservoirs. The streamline method can monitor the flow direction in the reservoir, injection efficiency, pore volume, and well allocation coefficient to determine the volume of fluid transferred between injection and production wells. Also, in recent years, many studies have been conducted on the effect of nanofluid injection on the characteristics of oil reservoirs and the increase in oil recovery. Since the streamline method has not been used to simulate the nanofluid injection in oil reservoirs, in this research the effect of water-silica nanofluid injection on the flow equations of phases has been investigated. The simulation results showed that nanofluid injection into the reservoir is more effective than pure water injection and increases oil production. Moreover, it was observed that the reservoir oil type (light and heavy) has an insignificant effect on the simulation results.
1. K. Mogensen, S. Masalmeh, J. Pet. Sci. Eng., 195, 107889 (2020).
2. S. Zendehboudi, M. A. Ahmadi, A. R. Rajabzadeh, N. Mahinpey, I. Chatzis, Can. J. Chem. Eng., 91(8), 1439-1449(2013).
3. Z. X. Xu, S. Y. Li, B. F. Li, D. Q. Chen, Z. Y. Liu, Z. M. Li, Pet. Sci., 17, 990-1013 (2020).
4. E. W. Al-Shalabi, K. Sepehrnoori, M. Delshad, (2013, April). Mechanisms behind low salinity water flooding in carbonate reservoirs. In SPE Western Regional & AAPG Pacific Section Meeting 2013 Joint Technical Conference. OnePetro.
5. M. Mahmoudpour, P. Pourafshary, J. Pet. Sci. Eng., 196, 107662(2021).
6. M. R. Aghajanzadeh, P. Ahmadi, M. Sharifi, M. Riazi, J. Pet. Sci. Eng., 178, 700-710 (2019).
7. I. Nowrouzi, A. Khaksar Manshad, A. H. Mohammadi, ACS omega, 7(26), 22161-22172(2022).
8. S. U. S. Choi, J. A. Eastman Heat Transfer Enhancement using Nanofluids. In International mechanical engineering congress and exhibition (1995).
9. M. Almahfood, B. Bai, J. Pet. Sci. Eng., 171, 196-210 (2018).
10. M. S. Alnarabiji, M. M. Husein, Fuel, 267, 117262 (2020).
11. L. Li, M. Khait, D. Voskov, A. Abushaikha, (2020, December). Parallel framework for complex reservoir simulation with advanced discretization and linearization schemes. In SPE Europec. OnePetro.
12. M. J. Blunt, K. Liu, M. R. Thiele, Pet. Geosci., 2(3), 259-269 (1996).
13. K. A. Lie, (2019). An introduction to reservoir simulation using MATLAB/GNU Octave: User guide for the MATLAB Reservoir Simulation Toolbox (MRST). Cambridge University Press.
14. M. H. Esfe, S. Esfandeh, J. Mol. Liq., 301, 112094 (2020).
15. N. A. Ogolo, O. A. Olafuyi, M. O. Onyekonwu, (2012, April). Enhanced oil recovery using nanoparticles. In SPE Saudi Arabia section technical symposium and exhibition. OnePetro.
16. M. F. El-Amin, S. Sun, A. Salama, (2013, March). Enhanced oil recovery by nanoparticles injection: modeling and simulation. In SPE Middle East Oil and Gas Show and Conference. OnePetro.
17. M. Sepehri, B. Moradi, A. Emamzadeh, A. H. Mohammadi, OGST - Revue d'IFP Energies nouvelles, 74, 5 (2019).
18. M.R. Thiele, R. P. Batycky, L. K. Thomas, (2002, September). Miscible WAG simulations using streamlines. In Paper presented at 8th European Conference on the Mathematics of Oil Recovery—Freiberg (Vol. 3, p. 6).
19. C.J. Seto, K. Jessen, F.M. Orr (2003, February). Compositional streamline simulation of field scale condensate vaporization by gas injection. In SPE Reservoir Simulation Symposium. OnePetro.
20. A.M. AlSofi, M. J. Blunt, SPE Journal, 15(04), 895-905 (2010).
21. A. Al-Huthali, A. Datta-Gupta, J. Pet. Sci. Eng., 43(3-4), 271-300 (2004).
22. M. Ahmadpour, M. Siavashi, M.H. Doranehgard, J. Cent. South Univ., 23, 2630-2637(2016).
23. Y. Jun, (2011). Streamline numerical well test interpretation: theory and method. Gulf Professional Publishing.
24. K.A. Lie, (2019). An introduction to reservoir simulation using MATLAB/GNU Octave: User guide for the MATLAB Reservoir Simulation Toolbox (MRST). Cambridge University Press.
