بررسی آزمایشگاهی مکانیسم جابه‌جایی میکروسکوپی سیلاب‌زنی مواد فعال سطحی در شرایط شوری و دمای بالا

نوع مقاله : مقاله پژوهشی

نویسندگان

1 دانشکده نفت اهواز، دانشگاه صنعت نفت، ایران

2 شرکت ملی مناطق نفت‌خیز جنوب، ایران

چکیده

میزان حجم بالای نفت غیرقابل استحصال مخازن کربناته به روش‌های اولیه هدفی مهم برای به‌کارگیری روش‌های ازدیاد برداشت شیمیایی نفت است. اما شرایط خاص این‌گونه مخازن نظیر دمای بالا، تجانس ناپذیری نمک‌های موجود در آب سازند و آب دریا و همچنین، ترشوندگی نفت‌دوست این مخازن از جمله عواملی هستند که تولید مطلوب از آنها را با چالش جدی مواجه می‌کنند. لذا در این پژوهش به بررسی پایداری، روند کاهش کشش سطحی و تغییر ترشوندگی لایه نفتی در اثر سیلاب‌زنی با استفاده از دو نوع ماده فعال سطحی آنیونی DSS و SDBS و دو نوع ماده فعال سطحی کاتیونی CTAB و CPC پرداخته شده است. ضریب بازیافت حاصل در اثر استفاده از این مواد به‌ترتیب 63، 48، 44 و 35% مشاهده گردید که بیشترین ضریب بازیافت در اثر اعمال ماده فعال سطحی DSS به‌دست آمد. همچنین، به ‌منظور بررسی تغییر ترشوندگی در اثر حضور ماده فعال سطحی در محیط متخلخل، نمونه سنگ مخزن به‌مدت دو هفته نفت‌دوست گردید و با اندازه‌گیری زاویه تماس °160 شرایط نفت‌دوستی به اثبات رسید. روند تغییر ترشوندگی در اثر زمان‌دهی با استفاده از دو نوع ماده فعال سطحی آنیونی DSS و SDB و دو نوع ماده فعال سطحی کاتیونی CTAB و CPC بررسی شد. زوایای تماس به‌دست ‌آمده به‌ترتیب °100، °90، °60 و °7/48 بوده است. بیشترین تغییر ترشوندگی در اثر استفاده از CPC مشاهده گردید. این ماده توانسته است زاویه تماس را از °160 به °7/48 تغییر دهد.
 

کلیدواژه‌ها

عنوان مقاله [English]

Experimental Investigation of the Microscopic Displacement Mechanisms of Surfactant Flooding in High Salinity and High Temperature Conditions

نویسندگان [English]

  • Sepideh Veiskarami 1
  • khalil shahbazi 1
  • saadat mohammadhosseinzadeh 2
1 Ahwaz Faculty of Petroleum, Petroleum University of Techrnology (PUT), Iran
2 National Iranian South Oil Company, Ahwaz, Iran
چکیده [English]

The high amount of trapped crude oil in carbonate reservoirs is the main objective of the various Enhanced Oil Recovery techniques. However, the harsh conditions of these reservoirs, such as high temperature, incompatibility of formation brine and sea water ions, as well as oil-wet conditions, are among the factors which face the desired approach with serious challenges. Therefore, in this study, the stability, interfacial tension, wettability alteration, and microvisual flooding experiments have been investigated using two types of anionic surfactants [DSS and SDBS] and two types of cationic surfactants [CTAB and CPC]. The amount of recovered oil was 63%, 48%, 44% and 35% respectively. The highest recovery factor was due to implementation of the DSS surfactant. Also, in order to investigate the effect of surfactant on the wettability alteration, the reservoir rock samples were aged for two weeks. Contact angle measurement of 160 degree has proved the oil wetness condition. Wettability alteration has been investigated using treating solutions of anionic surfactants DSS, SDB and cationic surfactants [CTAB and CPC]. Obtaining results demonstrate contact angles of 100, 90, 60 and 48.7 respectively. Finally, the highest wettability change is due to the application of CPC which alters the contact angle from 160 degrees to 48.7.
 

کلیدواژه‌ها [English]

  • Micro-model flooding
  • Surfactant
  • Rheology
  • Wettability Alteration
  • Contact Angle

مراجع

[1]. Adibhatia B., Sun X. and Mohanty K., “Numerical studies of oil production from initially oil-wet fracture blocks by surfactant brine imbibition,” SPE International Improved Oil Recovery Conference in Asia Pacific; 2005: Society of Petroleum Engineers. ##
[2]. Wang Y., Liu H. R., Wang J., Dong X. and Chen F., “Formulation development and visualized investigation of temperature-resistant and salt-tolerant surfactant-polymer flooding to enhance oil recovery,” Journal of Petroleum Science and Engineering, Vol. 174, 584-98, 2019. ##
[3]. Riswati S. S., Bae W., Park C., Permadi A. K., Efriza I. and Min B., “Experimental analysis to design optimum phrase type and salinity gradient of alkaline surfactant polymer flooding at low saline reservoir,” Journal of Petroleum Science and Engineering, Vol. 173, pp. 1005-1019, 2019. ##
[4]. Kumar K., Dao E. K. and Mohanty K. K., “Atomic force microscopy study of wettability alteration by surfactants,” SPE Journal, Vol. 13, No. 02, pp. 137-45, 2008. ##
[5]. Salehi M., Johnson S. J. and Liang J. T., “Mechanistic study of wettability alteration using surfactants with applications in naturally fractured reservoirs,” Langmuir, Vol. 24, No. 24, pp. 14099-14107, 2008. ##
[6]. Standnes D. C. and Austad T., “Wettability alteration in chralk: 2. Mechanism for wettability alteration from oil-wet to water-wet using surfactants,” Journal of Petroleum Science and Engineering, Vol. 28, No. 3, pp. 123-43, 2000. ##
[7]. Gupta R., Mohran K. and Mohranty K. K., “Surfactant screening for wettability alteration,” in oil-wet fractured carbonates, SPE Annual Technical Conference and Exhribition, Society of Petroleum Engineers, 2009. ##
[8]. Tie H. R., “Oil Recovery by spontaneous imbibition and viscous displacement from mixed-wet carbonates,” University of Wyoming, May 2006. ##
[9]. Edery Y., Weitz D. and Berg S., “Surfactant variations in porous media localize capillary instabilities during Haines jumps,” Physical Review Letters, Published, Vol. 120, Issue 2, 12 January 2018. ##
[10]. Shahrzad M., Ibnelwaleed A. and Abdullahr S., “Review on surfactant flooding: phase behavior, retention, IFT, and Field Applications,” Energy & Fuels, Vol. 31, No. 8, pp. 7701-7720, 2017. ##
[11]. Salehi M., “Enhancing the spontaneous imbibition process in naturally fractured reservoirs thrroughr wettability alteration using surfactants: Mechanistic study and feasibility of using biosurfactants produced from agriculture waste streams,” University of Kansas, 2009. ##
[12]. Standnes DC. “Enhanced oil recovery from oil-wet carbonate rock by spontaneous imbibition of aqueous surfactant solutions,” Fakultet for Naturvitenskap og Teknologi, 2001. ##
[13]. Masalmeh S. K., “Impact of capillary forces on residual oil saturation and flooding experiments for mixed to oil-wet carbonate reservoirs,” Proceedings of Society of Core Analysts Held in Aberdeen, Scotland, UK, SCA2012-11, 2012. ##
[14]. Thomas M. M., Clouse J. A., Longo J. M., “Adsorption of organic compounds on carbonate minerals: 1. Model compounds and their influence on mineral,” wettability, Chemical geology, Vol. 109, Issue 1-4, pp. 201-213, October 1993. ##
[15]. Alagic E. and Skauge A., “Combined low salinity brine injection and surfactant flooding in mixed− wet sandstone cores,” Energy & Fuels. Vol. 24, No. 6, pp. 3551-3559, 2010. ##
[16]. Alagic E., Spildo K., Skauge A. and Solbakken J., “Effect of crude oil ageing on low salinity and low salinity surfactant flooding,” Journal of Petroleum Science and Engineering, Vol. 78, No. 2, pp. 220-227, 2011. ##
[17]. Guillen V., Carvalho M. and Alvarado V., “Pore scale and macroscopic displacement mechanisms in emulsion flooding,” Transport in Porous Media. Vol. 94, Issue 1, pp. 197-206, April 2012. ##
[18]. Guillen V. R., Romero M. I., da Silveira Carvalho M. and Alvarado V., “Capillary-driven mobility control in macro emulsion flow in porous media,” International Journal of Multiphase Flow, Vol. 43, pp. 62-65, July 2012. ##
[19]. Tichelkamp T., Vu Y., Nourani M. and Øye G., “Interfacial tension between low salinity solutions of sulfonate surfactants and crude and model oils,” Energy & Fuels. Vol. 28, No. 4, pp. 2408-2414, 2014. ##
[20]. Chatterjee A., Moulik S., Sanyal S., Mishra B. and Puri P., “Thermodynamics of micelle formation of ionic surfactants: a critical assessment for sodium dodecyl sulfate, cetyl pyridinium chloride and dioctyl sulfosuccinate (Na salt) by microcalorimetric, conductometric, and tensiometric measurements,” The Journal of Phrysical Chemistry B., Vol. 105, No. 51, pp. 12823-12831, 2001.
[21]. Neugebauer J. M., “Detergents: an overview,” Methods in Enzymology, Vol. 182, pp. 239-253, 1990. ##
[22]. Harris E. and Angal S., “Protein purification application: a practical approach,” Oxford IRL Press, UK, Vol. 71, 1990. ##
[23]. Ray A., “Micelle formation in pure ethrylene glycol,” Journal of the American Chemical Society, Vol. 91, No. 23, pp. 6511-6512, 1969. ##
[24]. Maghzi A, Mohebbi A, Kharrat R, Ghazanfari MH., “Pore-scale monitoring of wettability alteration by silica nanoparticles during polymer flooding to heavy oil in a five-spot glass micromodel,” Transport in porous media, Vol. 87, No. 3, pp. 653-664, 2011. ##
[25]. Romero Zeron L. B., “The role of porous media wettability on foamed gel propagation and fluid diverting performance,” PhD thesis, pp. 3926-3926, 2005. ##
پژوهش نفت
دوره 29، 98-5 - شماره پیاپی 108
آذر و دی 1398
صفحه 73-84

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