Efficiency of Horizontal and Vertical Well Patterns on the Performance of Micellar-Polymer Flooding in Anisotropic Reservoirs

Kun Sang Lee

Abstract


There is increasing interest in micellar-polymer flooding because of the need to increase oil production from depleted and waterflooded reservoirs. Using horizontal wells for injection and production in a micellar-polymer flood process, higher sweep efficiency is expected compared with the use of conventional patterns by vertical wells. However, the use of horizontal wells is very sensitive to the well pattern designed to operate the process. This paper presents an analysis of how the overall performance of a micellar-polymer flood process in anisotropic reservoirs is influenced by the well pattern using horizontal injector and producer in different configurations. A three-dimensional numerical simulator for fluid flow and mass transport is used to analyze the effectiveness of well combinations in micellar-polymer applications. The potential for a horizontal well application was assessed through different situations in combinations of injection and production wells and degree of reservoir anisotropy. Results from the study have demonstrated that significant amount of oil can be recovered additionally and injectivity was remarkably improved by utilizing a combination of horizontal wells. The improvement of injectivity through a horizontal injection well was higher when it was combined with horizontal producer parallel to the injector. The overall performances in anisotropic reservoirs strongly depend on the type of wells considered and the orientation of the horizontal wells with respect to the permeability directions. Combination of horizontal wells placed parallel to the low permeability direction yields the best performance. In high permeability ratio reservoirs, the presence of horizontal injectors is more significant in defining the efficiency of the micellar-polymer flood than the horizontal producers.

Key words: Micellar-polymer flood; Horizontal well; Anisotropy; Injectivity


Keywords


Micellar-polymer flood; Horizontal well; Anisotropy; Injectivity

Full Text:

PDF

References


[1] Thomas, S., & Farouq Ali S. M. (2001). Micellar Flooding and ASP-Chemical Methods for Enhanced Oil Recovery, J. Canadian Petrol. Tech., 40(2), 46-52.

[2] Hirasaki, G. J., Miller, C. A., & Puerto, M. (2008). Recent Advances in Surfactant EOR, IPTC 115386, SPE Annual Technical Conference and Exhibition. September 21-24, Denver, CO.

[3] Taber, J. J., & Seright, R.S. (1992). Horizontal Injection and Production Wells for EOR or Waterflooding. SPE 23952 SPE Permian Basin Oil and Gas Conference. March 18-20, Midland, TX.

[4] Dakhlia, H., Wu, W., Lim, M. T., Delshad, M., Pope, G. A., & Sepehrnoori, K. (1995). Simulation of Surfactant Flooding Using Horizontal Wells. CIM 95-82, Petroleum Society of CIM 46th Annual Technical Meeting. June 7-9, Banff, Alberta, Canada.

[5] Westermark, R. V., Schmeling, J., Dauben, D. L., Robinowitz, S., & Weyland, H. V. (2006). Application of Horizontal Waterflooding to Improve Oil Recovery from Old Oil Fields. SPE 99668 SPE/DOE Symposium on Improved Oil Recovery. April 22-26 Tulsa, OK.

[6] Shedid, S. A. & Abbas, A. A. (2000). Comparison of Chemical Steam Floods Through Vertical and Horizontal Wells. CIM 65482 SPE/Petroleum Society of CIM International Conference on Horizontal Well Technology. November 6-8, Calgary, Alberta, Canada.

[7] Fadili, A., Kristensen, M.R., & Moreno, J. (2009). Smart Integrated Chemical EOR Simulation. IPTC 13762 International Petroleum Technology Conference. December 7-9, Doha, Qatar.

[8] Center for Petroleum and Geosystems Engineering (2000). UTCHEM-9.0 A three-dimensional chemical flood simulator. Austin: U. of Texas at Austin.

[9] Delshad, M., Pope, G. A., & Sepehrnoori, K. (1996). A Compositional Simulator for Modeling Surfactant Enhanced Aquifer Remediation, 1. Formulation. J. Contaminant Hydrol., 23(4), 303-327.




DOI: http://dx.doi.org/10.3968/j.est.1923847920120301.162

DOI (PDF): http://dx.doi.org/10.3968/g2378

Refbacks

  • There are currently no refbacks.


Copyright (c)




Share us to:   


Reminder

If you have already registered in Journal A and plan to submit article(s) to Journal B, please click the CATEGORIES, or JOURNALS A-Z on the right side of the "HOME".

We only use three mailboxes as follows to deal with issues about paper acceptance, payment and submission of electronic versions of our journals to databases: [email protected]; [email protected]; [email protected]

 Articles published in Energy Science and Technology are licensed under Creative Commons Attribution 4.0 (CC-BY).

 ENERGY SCIENCE AND TECHNOLOGY Editorial Office

Address: 1055 Rue Lucien-L'Allier, Unit #772, Montreal, QC H3G 3C4, Canada.
Telephone: 1-514-558 6138 
Website: Http://www.cscanada.net Http://www.cscanada.org 
E-mail[email protected]; [email protected]

Copyright © 2010 Canadian Research & Development Centre of Sciences and Cultures