Micro Foam Drilling Fluid Technology Abroad: New Progress and Discussion
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摘要: 综述了近10年国外微泡沫钻井液技术的研究及应用进展,总结了国外在微泡沫微观机理及其体系流变性能等方面取得的认识。针对目前的技术现状,提出了微泡沫尺寸与地层孔隙喉道半径匹配关系认识不清、微泡沫引起的堵塞、室内评价与现场应用效果差异较大等几方面的问题。在此基础上,分别从微泡沫体系在多孔介质中的渗流规律及影响因素、微泡沫钻井液用化学剂、微泡沫钻井液制备方法3个层面,探讨了该技术的研究方向。即要建立数学模型定量描述微泡沫尺寸与多孔介质中匹配关系,从而为微泡沫在不同储层中的应用提供理论参考;研究微泡沫产生的"贾敏效应"对储层流体渗流能力的影响,避免微泡沫钻井液施工后可能引起的产液量下降问题;建立实验室与现场制备条件的对应关系,统一关于微泡沫钻井液的制备规范或标准。Abstract: This paper summarizes progress made abroad on researches and application of micro foam drilling fluid in recent decade, including knowledge obtained about the micro mechanisms and rheology of micro foam drilling fluids. The authors present in the paper that, for the current technical status of the micro foam drilling fluids, the matching relationship between the sizes of foam and the sizes of pore throat is still not clearly understood; and there is a wide gap between laboratory evaluation on the blockage caused by micro foam and field application. Based on the problems presented above, the research direction of micro foam drilling fluid technology is discussed from three aspects, which are:the percolation flow pattern of micro foams in porous media and its affecting factors, chemical additives for micro foam drilling fluids, and the formulation method of micro foam drilling fluids. A mathematical model is needed to quantitatively describe the matching relationship between the sizes of micro foam and the sizes of pore throats in porous media, therefore to provide a theoretical reference for the application of micro foams in different reservoirs. The effects of "Jamin Effect" by the micro foams on the percolation flow capacity of reservoir fluids was studied to avoid the reduction of fluid production rate after operation with micro foam. Finally, the corresponding relation between laboratory experiment and field formulation conditions needs to be built up to unify the formulation criteria of micro foam drilling fluids.
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[1] GAURINA M E, DIMUREC.Paši-rudarsko-geološkonaftni zbornik.Aphron-based drilling fluids:solution for low pressure reservoirs[J]. Rudarsko-geološko-naftni zbornik, 2009, 21(4):65-72. [2] 邓柯, 许期聪, 邓虎, 等. 一种微泡沫基液体系在砂质黄土层雾化钻井中的应用[J]. 钻采工艺, 2012, 35(5):94-97.DENG Ke, XU Qicong, DENG Hu, et al. Application of a micro foam based liquid system in sandy clay mist drilling[J]. Drilling and Production Technology, 2012, 35(5):94-97. [3] FINK J K, DISPERSIONS, EMULSIONS, et al. Petroleum engineer's guide to oil field chemicals and fluids[M]. Boston:Gulf Professional Publishing, 2012, chapter21:663-694. [4] GROWCOCK F B, BELKIN A, FOSDICK M, et al. Recent advances in aphron drilling fluids[J]. SPE Drill Complet, 2007, 22(2):74-80. [5] AMIRI M C, WOODBURN E T. A method for the characterization of colloidal gas aphron dispersion[J]. Chem Eng Res Des, 1990, 68(10):154-160. [6] IVAN C D, BLAKE L D, QUINTANA J L. Aphronbase drilling fluid:Evolving technologies for lost circulation control[R]. SPE annual technical conference and exhibition. New Orleans, LA, USA:Society of Petroleum Engineers, SPE 67735, 2001. [7] GAURINA ME, IMUREC N, PAŠI B. Aphron-based drilling fluids:solution for low pressure reservoirs[J]. Rudarsko Geološko Naftni Zbornik, 2009, 21(5):65-72. [8] MATSUSHITA K, MOLLAH A H, STUCKEY D C, et al. Predispersed solvent extraction of dilute products using colloidal gas aphrons and colloidal liquid aphrons:Aphron preparation, stability and size[J]. Colloids and Surfaces, 1992, 69(1):65-72. [9] SADEGHIALIABADI H, AMIRI M C. A new stability index for characterizing the colloidal gas aphrons dispersion[J]. Colloids and Surfaces A, 2015(471):170-177. [10] AMIRI M C, MOSHKELANI M. Electrical conductivity as a novel technique for characterization of colloidal gas aphrons(CGA)[J]. Colloids and Surfaces A, 2008, 20(317):262-269. [11] JAUREGI P, VARLEY J. Colloidal gas aphrons:potential applications in biotechnology trends[J]. Biotechnology, 1999, 17(10):389-395. [12] MATSUSHITA K, MOLLAH A H, STUCKEY D C, et al. Predispersed solvent extraction of dilute products using colloidal gas aphrons and colloidal liquid aphrons:aphron preparation, stability and size[J]. Colloids Surf, 1992, 69(2):65-72. [13] BELKIN A, IRVING M, O'CONNOR R, et al. How aphron drilling flfluids work. SPE annual technical conference and exhibition[C]//Dallas, Texas, USA:SPE 96145, 2005. [14] JAUREGI P, MITCHELL G R, VARLEY J. Colloidal gas aphrons (CGA):dispersion and structural features[J]. Am. Inst. Chem. Eng. J., 2000, 46(10):24-36. [15] JAUREGI P, DERMIKI M. Separation of value-added bioproducts by colloidal gas aphrons (CGA) flotation and applications in the recovery of value-added food products. In:Rizvi S, editor[M]. Separation, extraction and concentration processes in the food, beverage and nutraceutical industries. Elsevier, 2010:284-313. [16] AMIRI M C, SADEGHIALIABADI H. Evaluating the stability of colloidal gas aphrons in the presence of montmorillonite nanoparticles[J]. Colloids and Surfaces A, 2014, 45(5):212-219. [17] FENG W, SINGHAL N, SWIFT S.Drainage mechanism of microbubble dispersion and factors influencing its stability[J]. Colloid Interface Sci, 2009, 337(8):548-554. [18] ALIZADEH A, KHAMEHCHI E. Mathematical modeling of the colloidal gas aphron motion through porous medium, including colloidal bubble generation and destruction[J]. Colloid and Polymer Science, 2016, 294(6):1075-1085. [19] NAREH M A, SHAHRI M P, ZAMANI M.Preparation and charac terization of colloid gas aphron based drilling flfluids using a plant-based surfactant[R]. SPE 16088, 2012. [20] BASU S, MALPANI P R. Removal of methyl orange and methylene blue dye from water using colloidal gas aphron-effect of processes parameter[J]. Sep Sci Technol, 2001, 36(13):2997-3013. [21] ROSSEN W R, ZHOU Z H, MAMUN C K. Modeling foam mobility in porous media[J].SPE Advanced Technology Series, 1995, 3(1):146-153. [22] ALIZADEH A, KHAMEHCHI E. A Model for predicting size distribution and liquid drainage from micro bubble surfactant multi-layer fluids using population balance[J]. Colloid and Polymer Science,2015,293(12):3419-3427. [23] ZITHA P L J, DU D X. A new stochastic bubble population model for foam flow in porous media[J]. Transport in Porous Media, 2010, 83(3):603-621. [24] BJORNDALEN N, ALVAREZ J M, JOSSY W E. An experimental study of the pore blocking mechanisms of Aphron drilling fluids using micro models[R].SPE 121417, 2009. [25] NBJORNDALE N, JOSE ALVAREZ, EDDIE JOSSY. A study of the effects of colloidal gas aphron composition on pore blocking[R].SPE 121417, 2011. [26] ALIZADEH A, KHAMEHCHI E.Mathematical modeling of the colloidal gas aphron motion through porous medium, including colloidal bubble generation and destruction[J]. Colloid and Polymer Science, 2016, 294(6):1075-1085. [27] ARABLOO NAREH'EI M, PORDEL SHAHRI M. Preparation and characterization of colloidal gas aphron based drilling fluids using a plant-based surfactant[R].SPE 160888, 2012. [28] KHAMEHCHI E, TABIBZADEH S, ALIZADEH A. Rheological properties of Aphron based drilling fluids[J]. Petroleum Exploration and Development, 2016, 43(6):1076-1081. [29] MACPHAIL W F, COOPER R C, BROOKEY T, et al. Adopting aphron fluid techno-logy for completion and work over applications[R]. SPE 112439, 2008. [30] GENTZIS T, DEISMAN N, CHALATURNYK R J. Effect of drilling fluids on coal permeability:Impact on horizontal wellbore stability[J]. International Journal of Coal Geology, 2009, 78(3):177-191. [31] GOKAVARAPU S, GANTLA S, PATEL J. An experimental study of aphron based drilling fluids[J]. Saint Petersburg, 2014, 10(10):186-190. [32] 牛步青, 黄维安, 王洪伟, 等. 聚胺微泡沫钻井液及其作用机理[J]. 钻井液与完井液, 2016, 32(6):30-34.NIU Buqing, HUANG Wei'an, WANG Hongwei, et al. Polyamine micro foam drilling fluid[J]. Drilling Fluid & Completion Fluid, 2016, 32(6):30-34. [33] 王健, 洪伟, 关键, 等. 泡沫随钻堵漏钻井液体系[J]. 钻井液与完井液, 2015, 32(3):23-26.WANG Jian, HONG Wei, GUAN Jian, et al. Study and application of foam LCM drilling fluid[J]. Drilling Fluid & Completion Fluid, 2015, 32(3):23-26. [34] 钟汉毅, 邱正松, 黄维安, 等. 胺类页岩抑制剂特点及研究进展[J]. 石油钻探技术, 2010, 38(1):104-108.ZHONG Hanyi, QIU Zhengsong, HUANG Weian, et al. Development and features of amine shale inhibitors[J]. Petroleum Drilling Techniques, 2010, 38(1):104-108.
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