A Critical Review of the Application of Nanomaterials in Frac Fluids: The State of the Art and Challenges

Wai Li, Jishan Liu, Jie Zeng, Jianwei Tian, Lin Li, Min Zhang, Jia Jia, Yufei Li, Hui Peng, Xionghu Zhao, Ji-wei Jiang
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引用次数: 10

Abstract

Nanomaterials have drawn considerable attention of the oil and gas industry due to their peculiar properties and interesting behaviors. Many experiments, trials and practices were conducted by petroleum scientists and engineers in the last two decades to use various novel nanomaterials to improve exploration and production. Based on the published literature, this article comprehensively reviews the strategies and experience of nanomaterial application in frac fluids, the current problems, and relevant challenges. Based on elaborated design, the nanomaterials such as nano-sized metal, metal oxide, silica, carbonate, carbon, polymer, fiber, organic-inorganic hybrid and other composites can be incorporated in frac fluids to greatly enhance or precisely tune the properties and performances. Consequently, nanomaterial-assisted frac fluids perform well in different aspects including density, rheology, stability, heat conductivity, specific heat capacity, fluid loss, breaking, clean up, proppant suspendability and frictional drag. To optimize the performance and cost-effectiveness of nano-frac fluids, advanced principles and theories in physical chemistry, heat and mass transfer, mechanics and rheology along with industrial design philosophy have been considered and applied. According to the investigation of the literature, nanomaterials have successfully fulfilled the following functions in frac fluids: (1) Improving the rheological behavior by intermolecular interactions (e.g., pseudo-crosslinking in frac fluids, or changing the aggregation pattern of surface-active molecules in surfactant based fluids); (2) Increasing the stability of fluids by enhancing the interfacial strength and toughness, especially in foams and emulsions; (3) Forming a low-permeability pseudo-filter cake to lower the fluid loss; (4) Increasing the viscosifying effect of polymers, which dramatically decreases the required loading of polymer in the fluid; (5) Boosting the thermal stability of frac fluids; (6) Improving the regained fracture conductivity; (7) Reducing the frictional drag of frac fluids; (8) Helping self-suspended proppants achieve better performance and (9) Reducing the required displacing pressure for the residual frac fluid by decreasing interfacial tension to help clean up. These achievements, along with the related design ideas, are reviewed. This paper also discusses the major difficulties and challenges for nano-frac fluids including compatibility, cost and HSE issues. Comprehensive laboratory work should be performed before field application to ensure the reliability of nano-assisted fluid formulations. Large-scale industrial production and a steady supply of nanomaterials will promote the application of nano-frac fluids. Exposure risk, eco-toxicity and biodegradability of nanomateials should be paid more attention. Incorporating the attractive, cutting-edged achievements in chemical and material sciences, nano-frac fluid is predicted to be fully accepted by the petroleum industry due to its great potential and the increasingly declining price of nanomaterials.
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纳米材料在压裂液中的应用综述:现状与挑战
纳米材料以其独特的性能和有趣的行为引起了石油天然气行业的广泛关注。在过去的二十年里,石油科学家和工程师们进行了许多实验、试验和实践,使用各种新型纳米材料来改善勘探和生产。本文基于已发表的文献,全面综述了纳米材料在压裂液中的应用策略和经验、当前存在的问题以及相关挑战。在精心设计的基础上,可以将纳米金属、金属氧化物、二氧化硅、碳酸盐、碳、聚合物、纤维、有机-无机杂化等纳米材料掺入压裂液中,大大提高或精确调整压裂液的性能和性能。因此,纳米材料辅助压裂液在密度、流变性、稳定性、导热性、比热容、失液、破碎、清理、支撑剂悬浮性和摩擦阻力等方面都表现良好。为了优化纳米压裂液的性能和成本效益,考虑并应用了物理化学、传热传质、力学和流变学的先进原理和理论以及工业设计理念。根据文献调查,纳米材料在压裂液中成功实现了以下功能:(1)通过分子间相互作用改善流变行为(如压裂液中的伪交联,或改变表面活性剂基流体中表面活性分子的聚集模式);(2)通过增强界面强度和韧性来提高流体的稳定性,特别是在泡沫和乳液中;(3)形成低渗伪滤饼,降低滤失;(4)提高了聚合物的增粘效果,大大降低了流体中所需的聚合物载荷;(5)提高压裂液热稳定性;(6)提高恢复的裂缝导流能力;(7)降低压裂液的摩擦阻力;(8)帮助自悬浮支撑剂获得更好的性能;(9)通过降低界面张力,降低残余压裂液所需的驱替压力,帮助清理。本文回顾了这些成就以及相关的设计思想。本文还讨论了纳米压裂液的主要困难和挑战,包括相容性、成本和HSE问题。在现场应用之前,需要进行全面的实验室工作,以确保纳米辅助流体配方的可靠性。大规模的工业生产和稳定的纳米材料供应将促进纳米压裂液的应用。纳米材料的暴露风险、生态毒性和生物降解性应引起更多的关注。纳米压裂液融合了化学和材料科学领域的前沿成果,由于其巨大的潜力和纳米材料价格的不断下降,预计将被石油工业完全接受。
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