English
Русский 28-47 p.
The problem of increasing the degree of oil recovery from reservoir formations has remained relevant over the past few decades.
Currently, there is a rapid increase in interest in chemical methods of increasing oil recovery to intensify oil production, in particular, flooding with surfactants (surfactants).
This article describes the factors affecting the efficiency of self-winding and the effect of adsorption on the eco-nomic component of the technology. To solve the problem of adsorption, preventing the large-scale introduction of surfactant, it is proposed to use the technology of microencapsulation of surfactants in a solid shell.
Currently, there is a rapid increase in interest in chemical methods of increasing oil recovery to intensify oil production, in particular, flooding with surfactants (surfactants).
This article describes the factors affecting the efficiency of self-winding and the effect of adsorption on the eco-nomic component of the technology. To solve the problem of adsorption, preventing the large-scale introduction of surfactant, it is proposed to use the technology of microencapsulation of surfactants in a solid shell.
1. Thomas S. Enhanced oil recovery – an overview. Oil and Gas Science and Technology. 2007. Vol. 63. P. 9 – 19.
2. Levitt D., Pope G.A. Selection and screening of polymers for enhanced-oil recovery. SPE Symposium on Im-proved Oil Recovery. 2008. Vol. 3. P. 20 – 23.
3. Gbadamosi A.O., Kiwalabye J., Junin R., Augustine A. A review of gas enhanced oil recovery schemes used in the North Sea. Journal of Petroleum Exploration and Production Technology. 2018. Vol. 5. P. 1 – 15.
4. Gbadamosi A.O., Junin R., Manan M., Agi A., Yusuff A. An overview of chemical enhanced oil recovery: recent advances and prospects. International Nano Letters. 2019. Vol. 9. P. 171 – 202.
5. Yernazarova A., Kaiyrmanova G., Baubekova A., Zhubanova A.A. Microbial enhanced oil recovery. In book: Chemical Enhanced Oil Recovery (cEOR) – a Practical Overview. 2016. P. 148 – 166.
6. Thomas S., Farouq A.S. Micellar flooding and ASP-chemical methods for enhanced oil recovery. Journal of Canadian Petroleum Technology. 2001. Vol. 40 (2). P. 46 – 52.
7. Mandal A., Samanta A., Ojha K. Mobility control and enhanced oil recovery using partially hydrolysed poly-acrylamide (PHPA). International Journal of Oil, Gas and Coal Technology. 2013. Vol. 6 (3). P. 245 – 258.
8. Abbas A.H., Sulaiman W.R.W., Jaafar M.Z., Gbadamosi A.O., Ebrahimi S.S., Elrufai A. Numerical study for continuous surfactant flooding considering adsorption in heterogeneous reservoir. Journal of King Saud University – Engineering Sciences. 2018. Vol. 5. P. 1 – 9.
9. Gong H., Li Y., Dong M., Ma S., Liu W. Effect of wettability alteration on enhanced heavy oil recovery by alkaline flooding. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2016. Vol. 488. P. 28 – 35.
10. Azam M.R., Tan I.M., Ismail L., Mushtaq M., Nadeem M., Sagir M. Static adsorption of anionic surfactant onto crushed Berea sandstone. Journal of Petroleum Exploration and Production Technology. 2013. Vol. 3 (3). P. 195 − 201.
11. Kamal M., Hussein I., Sultan A. Review on surfactant flooding: Phase behavior, retention, IFT, and field applications. Energy and Fuels. 2017. Vol. 31 (8). P. 7701 – 7720.
12. Tavakkoli O., Kamyab H., Shariati M. Effect of nanoparticles on the performance of polymer/surfactant flooding for enhanced oil recovery: A review. Fuel. 2022. Vol. 321. P. 122867.
13. Tabaeh Havavi M., Kazemzadeh Y., Riazi M. Application of surfactant-based enhanced oil recovery in car-bonate Reservoirs: A critical review of the opportunities and challenges. Chemical Physics Letters. 2022. Vol. 806 (1). P. 124090.
14. Shakeel M., Samanova A., Pourafshary P., Hashmet M. Optimization of low salinity water/surfactant flood-ing design for oil-wet carbonate reservoirs by introducing a negative salinity gradient. Energies. 2022. Vol. 15 (24). P. 9400.
15. Pashapurieganeh F., Zargar G., Kadkholate A., Rabiee A., Misaghi. A., Zakariaei S. Experimental evaluation of designed and synthesized Alkaline-Surfactant-polymer (ASP) for chemical flooding in car-bonate reservoirs. Fuel. 2022. Vol. 321. P. 1 – 17.
16. Adila A., Ai-Shalabi E., AlAmeri W. Recent developments in surfactant flooding for carbonate reser-voirs under harsh conditions. Offshore Technology Conference Asia. Malaysia. 2020.
17. Sheng J.J. Status of surfactant EOR technology. Petroleum. 2015. Vol. 1 (2). P. 97 − 105.
18. Wu Y., Iglauer S., Shuler P., Tang Y., Goddard W. A. Branched alkyl alcohol propoxylated sulfate surfac-tants for improved oil recovery. Tenside, Surfactants, Detergents. 2010. Vol. 47(3). P. 152 − 161.
19. Yu Q., Jiang H., Zhao C. Study of interfacial tension between oil and surfactant polymer flooding. Petroleum Science Technologies. 2010. Vol. 28(18). P. 1846 – 1854.
20. Guo H., Song K., Hilfer R. A brief review of capillary number and its use in capillary desaturation curves. Transport in Porous Media. 2022. Vol. 144(1). P. 3 – 31.
21. Howe A. M., Clarke A., Mitchell J., Staniland J., Hawkes L., Whalan C. Visualising surfactant en-hanced oil recovery. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2015. Vol. 480. P. 449 – 461.
22. Hou J., Liu Z., Zhang S., Yue X., Yang J. The role of viscoelasticity of alkali/surfactant/polymer solu-tions in enhanced oil recovery. Journal of Petroleum Science and Engineering. 2005. Vol. 47 (3-4). P. 219 − 235.
23. Daoshan L., Shouliang L., Yi L., Demin, W. The effect of biosurfactant on the interfacial tension and ad-sorption loss of surfactant in ASP flooding. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2004. Vol. 244 (1-3). P. 53 – 60.
24. Wanli K., Yi L., Baoyan Q., Guangzhi L., Zhenyu Y., Jichun H. Interactions between alka-li/surfactant/polymer and their effects on emulsion stability. Colloids and Surfaces A: Physicochemical and Engi-neering Aspects. 2000. Vol. 175 (1-2). P. 243 − 247.
25. Bortolotti, V.; Macini, P.; Srisuriyachai, F. Laboratory evaluation of alkali and alkali-surfactant-polymer flooding combined with intermittent flow in carbonatic rocks. Asia Pacific Oil and Gas Confer-ence & Exhibition. 2009. Vol. 1. P. 366 – 378.
26. Nesmerak K., Nemcova Irena Determination of critical micelle concentration by electrochemical means. Analytical Letters. Vol. 39 (6). P. 1023 – 1040.hl
27. Miquilena A., Coll V., Borges A., Melendez J., Zeppieri S. Influence of drop growth rate and size on the in-terfacial tension of Triton X-100 solutions as a function of pressure and temperature. International Journal of Thermophysics. 2010. Vol. 31 (11-12). P. 2416 – 2424.
28. Aoudia M., Al-Maamari R. S., Nabipour M., Al-Bemani A. S., Ayatollahi S. Laboratory study of alkyl ether sulfonates for improved oil recovery in high-salinity carbonate reservoirs: A case study. Energy Fuels. 2010. Vol. 24 (6). P. 3655 − 3660.
29. Benzagouta M., Kadnanda W., AlQuraishiA., Amro M. Effect of temperature, pressure, salinity, and surfac-tant concentration on IFT for surfactant flooding optimization. Arabian Journal of Geoscience. 2013. Vol. 6 (9). P. 3535 – 3544.
30. El-Batanoney M., Abdel-Moghny T., Ramzi M. The effect of mixed surfactants on enhancing oil recovery. Journal of Surfactants and Detergents. 1999. Vol. 2 (2). P. 201 – 205.
31. Hosseni S., Shuker M.T., Tomocene J. The role of salinity and brine ions in interfacial tension reduction while using surfactant for enhanced oil recovery. Research Journal of Applied Science, Engineering and Technolo-gy. 2015. Vol. 9 (9). P. 722 – 726.
32. Wu Y., Iglauer S., Shuler P., Tang Y., Goddard W. A. Branched alkyl alcohol propoxylated sulfate surfac-tants for improved oil recovery. Tenside, Surfactants, Detergents. 2010. Vol. 47 (3). P. 152 − 161.
33. Li G., Mu J., Li Y., Yuan S. An experimental study on alkaline/surfactant/polymer flooding systems using nature mixed carboxylate. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2000. Vol. 173 (1-3). P. 219 – 229.
34. Gao B., Sharma M. A family of alkyl sulfate gemini surfactants. 2. Water-oil interfacial tension reduction. Journal of Colloid and Interface Science. 2013. Vol. 407. P. 375 – 381.
35. Li G., Mu J., Li Y. An experimental study on alkaline/surfactant/polymer flooding systems using na-ture mixed carboxylate. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2000. Vol. 173 (1-3). P. 219 – 229.
36. Chang L., Pope G. A new surfactant wettability alteration model for reservoir simulators. Journal of Surfac-tants and Detergents. 2023. Vol. 26 (3). P. 437 – 451.
37. Lag J., Hadas A., Fairbridge R.W., Novoa Munoz J.C. Hydrophilicity, hydrohobisity. In book: En-cyclopedia of Soil Science. 2008. P. 329-330.
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40. Standnes S.D., Austad T. Wettability alteration in chalk: 2. Mechanism for wettability alteration from oil-wet to water-wet using surfactants. Journal of Petroleum Science and Engineering. 2000 Vol. 28 (3). R. 123 − 143.
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42. Budhathoki M., Barnee S. H. R., Shiau B.-J., Harwell, J. H. Improved oil recovery by reducing surfactant adsorption with polyelectrolyte in high saline brine. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2016. Vol. 498. P. 66 – 73.
43. AlSofi A., Fuseni A., Zhou X., Hassan S. Development of chemical EOR formulations for a high tempera-ture and high salinity carbonate reservoir. Society of Petroleum Engineers - International Petroleum Technology Conference 2013, IPTC 2013: Challenging Technology and Economic Limits to Meet the Global Energy Demand. 2013. Vol. 6. P. 4946 – 4958.
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2. Levitt D., Pope G.A. Selection and screening of polymers for enhanced-oil recovery. SPE Symposium on Im-proved Oil Recovery. 2008. Vol. 3. P. 20 – 23.
3. Gbadamosi A.O., Kiwalabye J., Junin R., Augustine A. A review of gas enhanced oil recovery schemes used in the North Sea. Journal of Petroleum Exploration and Production Technology. 2018. Vol. 5. P. 1 – 15.
4. Gbadamosi A.O., Junin R., Manan M., Agi A., Yusuff A. An overview of chemical enhanced oil recovery: recent advances and prospects. International Nano Letters. 2019. Vol. 9. P. 171 – 202.
5. Yernazarova A., Kaiyrmanova G., Baubekova A., Zhubanova A.A. Microbial enhanced oil recovery. In book: Chemical Enhanced Oil Recovery (cEOR) – a Practical Overview. 2016. P. 148 – 166.
6. Thomas S., Farouq A.S. Micellar flooding and ASP-chemical methods for enhanced oil recovery. Journal of Canadian Petroleum Technology. 2001. Vol. 40 (2). P. 46 – 52.
7. Mandal A., Samanta A., Ojha K. Mobility control and enhanced oil recovery using partially hydrolysed poly-acrylamide (PHPA). International Journal of Oil, Gas and Coal Technology. 2013. Vol. 6 (3). P. 245 – 258.
8. Abbas A.H., Sulaiman W.R.W., Jaafar M.Z., Gbadamosi A.O., Ebrahimi S.S., Elrufai A. Numerical study for continuous surfactant flooding considering adsorption in heterogeneous reservoir. Journal of King Saud University – Engineering Sciences. 2018. Vol. 5. P. 1 – 9.
9. Gong H., Li Y., Dong M., Ma S., Liu W. Effect of wettability alteration on enhanced heavy oil recovery by alkaline flooding. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2016. Vol. 488. P. 28 – 35.
10. Azam M.R., Tan I.M., Ismail L., Mushtaq M., Nadeem M., Sagir M. Static adsorption of anionic surfactant onto crushed Berea sandstone. Journal of Petroleum Exploration and Production Technology. 2013. Vol. 3 (3). P. 195 − 201.
11. Kamal M., Hussein I., Sultan A. Review on surfactant flooding: Phase behavior, retention, IFT, and field applications. Energy and Fuels. 2017. Vol. 31 (8). P. 7701 – 7720.
12. Tavakkoli O., Kamyab H., Shariati M. Effect of nanoparticles on the performance of polymer/surfactant flooding for enhanced oil recovery: A review. Fuel. 2022. Vol. 321. P. 122867.
13. Tabaeh Havavi M., Kazemzadeh Y., Riazi M. Application of surfactant-based enhanced oil recovery in car-bonate Reservoirs: A critical review of the opportunities and challenges. Chemical Physics Letters. 2022. Vol. 806 (1). P. 124090.
14. Shakeel M., Samanova A., Pourafshary P., Hashmet M. Optimization of low salinity water/surfactant flood-ing design for oil-wet carbonate reservoirs by introducing a negative salinity gradient. Energies. 2022. Vol. 15 (24). P. 9400.
15. Pashapurieganeh F., Zargar G., Kadkholate A., Rabiee A., Misaghi. A., Zakariaei S. Experimental evaluation of designed and synthesized Alkaline-Surfactant-polymer (ASP) for chemical flooding in car-bonate reservoirs. Fuel. 2022. Vol. 321. P. 1 – 17.
16. Adila A., Ai-Shalabi E., AlAmeri W. Recent developments in surfactant flooding for carbonate reser-voirs under harsh conditions. Offshore Technology Conference Asia. Malaysia. 2020.
17. Sheng J.J. Status of surfactant EOR technology. Petroleum. 2015. Vol. 1 (2). P. 97 − 105.
18. Wu Y., Iglauer S., Shuler P., Tang Y., Goddard W. A. Branched alkyl alcohol propoxylated sulfate surfac-tants for improved oil recovery. Tenside, Surfactants, Detergents. 2010. Vol. 47(3). P. 152 − 161.
19. Yu Q., Jiang H., Zhao C. Study of interfacial tension between oil and surfactant polymer flooding. Petroleum Science Technologies. 2010. Vol. 28(18). P. 1846 – 1854.
20. Guo H., Song K., Hilfer R. A brief review of capillary number and its use in capillary desaturation curves. Transport in Porous Media. 2022. Vol. 144(1). P. 3 – 31.
21. Howe A. M., Clarke A., Mitchell J., Staniland J., Hawkes L., Whalan C. Visualising surfactant en-hanced oil recovery. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2015. Vol. 480. P. 449 – 461.
22. Hou J., Liu Z., Zhang S., Yue X., Yang J. The role of viscoelasticity of alkali/surfactant/polymer solu-tions in enhanced oil recovery. Journal of Petroleum Science and Engineering. 2005. Vol. 47 (3-4). P. 219 − 235.
23. Daoshan L., Shouliang L., Yi L., Demin, W. The effect of biosurfactant on the interfacial tension and ad-sorption loss of surfactant in ASP flooding. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2004. Vol. 244 (1-3). P. 53 – 60.
24. Wanli K., Yi L., Baoyan Q., Guangzhi L., Zhenyu Y., Jichun H. Interactions between alka-li/surfactant/polymer and their effects on emulsion stability. Colloids and Surfaces A: Physicochemical and Engi-neering Aspects. 2000. Vol. 175 (1-2). P. 243 − 247.
25. Bortolotti, V.; Macini, P.; Srisuriyachai, F. Laboratory evaluation of alkali and alkali-surfactant-polymer flooding combined with intermittent flow in carbonatic rocks. Asia Pacific Oil and Gas Confer-ence & Exhibition. 2009. Vol. 1. P. 366 – 378.
26. Nesmerak K., Nemcova Irena Determination of critical micelle concentration by electrochemical means. Analytical Letters. Vol. 39 (6). P. 1023 – 1040.hl
27. Miquilena A., Coll V., Borges A., Melendez J., Zeppieri S. Influence of drop growth rate and size on the in-terfacial tension of Triton X-100 solutions as a function of pressure and temperature. International Journal of Thermophysics. 2010. Vol. 31 (11-12). P. 2416 – 2424.
28. Aoudia M., Al-Maamari R. S., Nabipour M., Al-Bemani A. S., Ayatollahi S. Laboratory study of alkyl ether sulfonates for improved oil recovery in high-salinity carbonate reservoirs: A case study. Energy Fuels. 2010. Vol. 24 (6). P. 3655 − 3660.
29. Benzagouta M., Kadnanda W., AlQuraishiA., Amro M. Effect of temperature, pressure, salinity, and surfac-tant concentration on IFT for surfactant flooding optimization. Arabian Journal of Geoscience. 2013. Vol. 6 (9). P. 3535 – 3544.
30. El-Batanoney M., Abdel-Moghny T., Ramzi M. The effect of mixed surfactants on enhancing oil recovery. Journal of Surfactants and Detergents. 1999. Vol. 2 (2). P. 201 – 205.
31. Hosseni S., Shuker M.T., Tomocene J. The role of salinity and brine ions in interfacial tension reduction while using surfactant for enhanced oil recovery. Research Journal of Applied Science, Engineering and Technolo-gy. 2015. Vol. 9 (9). P. 722 – 726.
32. Wu Y., Iglauer S., Shuler P., Tang Y., Goddard W. A. Branched alkyl alcohol propoxylated sulfate surfac-tants for improved oil recovery. Tenside, Surfactants, Detergents. 2010. Vol. 47 (3). P. 152 − 161.
33. Li G., Mu J., Li Y., Yuan S. An experimental study on alkaline/surfactant/polymer flooding systems using nature mixed carboxylate. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2000. Vol. 173 (1-3). P. 219 – 229.
34. Gao B., Sharma M. A family of alkyl sulfate gemini surfactants. 2. Water-oil interfacial tension reduction. Journal of Colloid and Interface Science. 2013. Vol. 407. P. 375 – 381.
35. Li G., Mu J., Li Y. An experimental study on alkaline/surfactant/polymer flooding systems using na-ture mixed carboxylate. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2000. Vol. 173 (1-3). P. 219 – 229.
36. Chang L., Pope G. A new surfactant wettability alteration model for reservoir simulators. Journal of Surfac-tants and Detergents. 2023. Vol. 26 (3). P. 437 – 451.
37. Lag J., Hadas A., Fairbridge R.W., Novoa Munoz J.C. Hydrophilicity, hydrohobisity. In book: En-cyclopedia of Soil Science. 2008. P. 329-330.
38. Standnes D.C., Austad T. Wettability alteration in chalk: 2. Mechanism for wettability alteration from oil-wet to water-wet using surfactants. Journal of Petroleum Science and Engineering. 2000. Vol. 28 (3). P. 123 – 143.
39. Moisio M.T., Clouse J.A., Longo M.J. Adsorption of organic compounds on carbonate minerals: 1. Model compounds and their influence on mineral wettability. Chemical Geology. 1993 Vol. 109 (1) R. 201 – 213.
40. Standnes S.D., Austad T. Wettability alteration in chalk: 2. Mechanism for wettability alteration from oil-wet to water-wet using surfactants. Journal of Petroleum Science and Engineering. 2000 Vol. 28 (3). R. 123 − 143.
41. Barati-Harooni A., Najafi-Marghmaleki A.; Tatar, A.; Mohammadi, A. H. Experimental and modeling stud-ies on adsorption of a nonionic surfactant on sandstone minerals in enhanced oil recovery process with surfactant flooding. Journal of Molecular Liquids. 2016. Vol. 220. P. 1022 − 1032.
42. Budhathoki M., Barnee S. H. R., Shiau B.-J., Harwell, J. H. Improved oil recovery by reducing surfactant adsorption with polyelectrolyte in high saline brine. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 2016. Vol. 498. P. 66 – 73.
43. AlSofi A., Fuseni A., Zhou X., Hassan S. Development of chemical EOR formulations for a high tempera-ture and high salinity carbonate reservoir. Society of Petroleum Engineers - International Petroleum Technology Conference 2013, IPTC 2013: Challenging Technology and Economic Limits to Meet the Global Energy Demand. 2013. Vol. 6. P. 4946 – 4958.
44. Biswas S.C., Chattoraj D. K. Kinetics of adsorption of cationic surfactants at silica-water interface. Journal of Colloid and Interface Science. 1998. Vol. 205 (1). R. 12 − 20.
45. Somasundaran P., Huang L. Adsorption/aggregation of surfactants and their mixtures at solid-liquid inter-faces. Advances in Colloid and Interface Science. 2000. Vol. 88 (1). R. 179 − 208.
46. Azam M. R., Tan I. M., Ismail L., Mushtaq M., Nadeem M., Sagir M. Static adsorption of anionic sur-factant onto crushed Berea sandstone. Journal of Petroleum Exploration and Production Technology. 2013. Vol. 3 (3). R. 195 − 201.
47. Kalam S., Abu-Khamsin S.A., Pati S. Surfactant adsorption isotherms: A review. ACS Omega. 2012. Vol. 6 (48). R. 32342 – 32348.
48. Solairaj S., Britton C., Kim D. H., Weerasooriya U., Pope G. A. Measurement and analysis of surfactant re-tention. SPE – DOE Improved Oil Recovery Symposium Proceedings. 2012. Vol. 2. R. 294 – 1310.
49. Golub T., Koopal L., Sidorova M. Adsorption of cationic surfactants on silica surface: 1. Adsorption iso-therms and surface charge. Colloid Journal. 2004. Vol. 66 (1). P. 38 – 43.
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