纳米颗粒在非常规油藏水力压裂中的应用进展
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摘要
本文综述了纳米颗粒在非常规储层水力压裂中的应用现状,重点介绍了纳米颗粒的作用机理、应用、研究成果、技术挑战和未来研究方向。并指出纳米材料在改善粘弹性表面活性剂流体、泡沫基流体和聚合物基压裂液流变学方面的应用前景。以往的研究结果表明,纳米材料具有尺寸小、比表面积大、磁性能强、强度和稳定性好等独特的性能,可以应用于井下纳米传感器、纳米支撑剂、破胶剂和降滤失剂的开发。
In this paper, the application status of nanoparticles in unconventional reservoir hydraulic fracturing is reviewed, with emphasis on the mechanism, application, research achievements, technical challenges and future research directions of nanoparticles.The applications of nanomaterials in improving rheology of viscoelastic surfactant fluids, foam-based fluids and polymer-based fracturing fluids are reviewed.Previous research results show that nanomaterials have such unique properties as small size, large specific surface area, strong magnetic properties,good strength and stability, which can be applied to the development of downhole nano-sensors, nano-proppant, gel breaker and filter loss agent.
In this paper, the application status of nanoparticles in unconventional reservoir hydraulic fracturing is reviewed, with emphasis on the mechanism, application, research achievements, technical challenges and future research directions of nanoparticles.The applications of nanomaterials in improving rheology of viscoelastic surfactant fluids, foam-based fluids and polymer-based fracturing fluids are reviewed.Previous research results show that nanomaterials have such unique properties as small size, large specific surface area, strong magnetic properties,good strength and stability, which can be applied to the development of downhole nano-sensors, nano-proppant, gel breaker and filter loss agent.
引文
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[16] Verma A,Chauhan G,Baruah P P,et al. Morphology,Rheology,and Kinetics of Nanosilica Stabilized Gelled Foam Fluid for Hydraulic Fracturing Application[J]. Industrial&Engineering Chemistry Research,2018.
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[19] Anandan R,Barati R,Johnson S,et al. Polyelectrolyte Complex Stabilized CO2Foam Systems for Improved Fracture Conductivity and Reduced Fluid Loss[J]. International Hydraulic Fracturing Technology Conference and Exhibition,2018,(10):16-18.
[20]肖博,蒋廷学,张正道,等.纳米复合纤维基表面活性剂压裂液性能评价[J].科学技术与工程,2018,18(29):64-69.
[21]张珈铭,张焕芝,王敬瑶,等.纳米技术在油气田开发中的应用[J].仪表技术与传感器,2018,(4):112-116.
[22]夏冰冰.改性碳纳米管增韧树脂覆膜砂支撑剂的制备与性能研究[D].西安石油大学,2017.
[23]冯萍,邱正松,曹杰.交联型油基钻井液降滤失剂的合成及性能评价[J].钻井液与完井液,2012,(1):9-11;14;89;90.
[24] Barati R,JohnsonS,Mccool S,et al. Fracturing fluid cleanup by controlled release of enzymes from polyelectrolyte complex nanoparticles[J]. Journal of Applied Polymer Science,2011(3):1292-1298.
[2]张敬春.纳米材料在压裂液中的应用研究进展[J].化工中间体,2015,(10):26-27.
[3]王彦玲,王坤,金家锋,等.纳米材料在压裂液体系中的应用进展[J].精细石油化工,2016,(6):63-67.
[4]鲁大丽,陈勇,张俊,等.改性聚合物压裂液的合成及其性能[J].应用化学,2018,35(11):1295-1300.
[5]赵晓航.纳米颗粒改性VES压裂液的工程特性及分子动力学模拟研究[D]. 2018.
[6]谭明文,何兴贵,张绍彬,等.泡沫压裂液研究进展[J].钻采工艺,2008,31(5):129-132;173.
[7]李杨,郭建春,王世彬,等.低伤害压裂液研究现状及发展趋势[J].现代化工,2018,38(9):20-22;24.
[8]章子锋.胍胶压裂液高效纳米交联剂的制备及其性能研究[D].河南大学,2017.
[9]杨兆中,朱静怡,李小刚,等.含纳米颗粒的黏弹性表面活性剂泡沫压裂液性能[J].科学技术与工程,2018,18(10):42-47.
[10]李彦尊,武文涛,陈刚.纳米颗粒在超临界CO2压裂中的作用评价[J].煤炭技术,2016,35(9):136-139.
[11]吴越琼.纳米颗粒改性粘弹性清洁压裂液的流变特性研究[D].浙江大学,2015.
[12]石亚丽. VES压裂液用可降解表面活性剂的合成及性能评价[D].华中科技大学,2016.
[13] Luo M,Jia Z,Sun H,et al. Rheological behavior and microstructure of an anionic surfactant micelle solution with pyroelectric nanoparticle[J]. Colloids and Surfaces A(Physicochemical and Engineering Aspects),2012,395:267-275.
[14]杨兆中,朱静怡,李小刚,等.含纳米颗粒的黏弹性表面活性剂泡沫压裂液性能[J].科学技术与工程,2018,18(10):42-47.
[15] Emrani A,Ibrahim A,Nasr-El-Din,H,et al. Mobility Control using Nanoparticle-Stabilized CO2Foam as a Hydraulic Fracturing Fluid[J]. SPE Europec featured at 79th EAGE Conference and Exhibition,2017,(6):12-15.
[16] Verma A,Chauhan G,Baruah P P,et al. Morphology,Rheology,and Kinetics of Nanosilica Stabilized Gelled Foam Fluid for Hydraulic Fracturing Application[J]. Industrial&Engineering Chemistry Research,2018.
[17]梁国琦.表面功能化纳米颗粒与蠕虫状胶束作用机制研究[D]. 2018.
[18] Hosseini H,Tsau J,Peltier,E,et al. Lowering Fresh Water Usage in Hydraulic Fracturing by Stabilizing sc CO2Foam with Polyelectrolyte Complex Nanoparticles Prepared in High Salinity Produced Water[J]. SPE International Conference and Exhibition on Formation Damage Control,2018,(2):7-9.
[19] Anandan R,Barati R,Johnson S,et al. Polyelectrolyte Complex Stabilized CO2Foam Systems for Improved Fracture Conductivity and Reduced Fluid Loss[J]. International Hydraulic Fracturing Technology Conference and Exhibition,2018,(10):16-18.
[20]肖博,蒋廷学,张正道,等.纳米复合纤维基表面活性剂压裂液性能评价[J].科学技术与工程,2018,18(29):64-69.
[21]张珈铭,张焕芝,王敬瑶,等.纳米技术在油气田开发中的应用[J].仪表技术与传感器,2018,(4):112-116.
[22]夏冰冰.改性碳纳米管增韧树脂覆膜砂支撑剂的制备与性能研究[D].西安石油大学,2017.
[23]冯萍,邱正松,曹杰.交联型油基钻井液降滤失剂的合成及性能评价[J].钻井液与完井液,2012,(1):9-11;14;89;90.
[24] Barati R,JohnsonS,Mccool S,et al. Fracturing fluid cleanup by controlled release of enzymes from polyelectrolyte complex nanoparticles[J]. Journal of Applied Polymer Science,2011(3):1292-1298.