双聚合物压裂液比传统压裂液更具优势

Tariq Almubarak
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引用次数: 0

摘要

随着石油和天然气勘探的继续进行,有必要从较深、低渗透率和较高温度的地层中开采。由于页岩独特的地质力学特性,非常规页岩地层采用滑溜水压裂液。另一方面,常规地层需要交联压裂液来适当提高产能。瓜尔及其衍生物在交联水力压裂液方面取得了成功。然而,它们需要更高的聚合物负载来承受更高的温度环境。这导致混合时间和添加剂要求的增加。最重要的是,由于聚合物载荷高,它们不会完全破裂,会产生残留的聚合物碎片,从而堵塞地层,显著降低裂缝导流能力。研制了一种新型混合型双聚合物水力压裂液。该流体由瓜尔胶衍生物和基于聚丙烯酰胺的合成聚合物组成。与传统压裂液相比,这种新型压裂液易于水化,需要的添加剂更少,可以动态混合,并且能够在低聚合物负载下保持优异的流变性能。聚合物混合物溶液的总聚合物浓度为20至40 lb/1,000 gal,体积比为2:1,1:1和1:2。这些液体用金属交联剂交联,并用氧化剂在300°F下破碎。测试的重点是交联剂与聚合物的比例分析,以有效降低载荷,同时在该温度下保持足够的支撑剂性能。高压/高温流变仪用于测量粘度、储存模量和流体破碎性能。支撑剂沉淀采用高温高压老化池和高温高压透明池。FTIR, Cryo-SEM和HP/HT流变仪也被用来了解相互作用。结果表明,双聚合物压裂液在300°F和100 s-1条件下能够产生稳定的粘度。结果表明,双聚合物压裂液比单聚合物压裂液具有更高的黏度。此外,正确理解和调整交联剂与聚合物的比例可以在20lb / 1000gal条件下获得优异的性能。这两种聚合物形成了改进的交联网络,增强了支撑剂的携带性能。它还展示了清洁和可控的断裂性能与氧化剂。首次进行了大量的实验来评价新的双聚合物体系。该体系表现出多糖和聚丙烯酰胺族之间的正向相互作用,并产生了优异的流变性能。使用混合聚合物体系的主要好处是减少聚合物负载。低载荷是非常理想的,因为它可以降低材料成本,简化现场操作,并可能降低对裂缝面、支撑剂充填层和地层的损害。
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Dual-Polymer Fracturing Fluids Provide Major Advantages Over Traditional Fluids
As exploration for oil and gas continues, it becomes necessary to produce from deeper formations, have low permeability, and higher temperature. Unconventional shale formations utilize slickwater fracturing fluids due to the shale’s unique geomechanical properties. On the other hand, conventional formations require crosslinked fracturing fluids to properly enhance productivity. Guar and its derivatives have a history of success in crosslinked hydraulic fracturing fluids. However, they require higher polymer loading to withstand higher temperature environments. This leads to an increase in mixing time and additive requirements. Most importantly, due to the high polymer loading, they do not break completely and generate residual polymer fragments that can plug the formation and reduce fracture conductivity significantly. In this work, a new hybrid dual polymer hydraulic fracturing fluid is developed. The fluid consists of a guar derivative and a polyacrylamide-based synthetic polymer. Compared to conventional fracturing fluids, this new system is easily hydrated, requires fewer additives, can be mixed on the fly, and is capable of maintaining excellent rheological performance at low polymer loadings. The polymer mixture solutions were prepared at a total polymer concentration of 20 to 40 lb/1,000 gal and at a volume ratio of 2:1, 1:1, and 1:2. The fluids were crosslinked with a metallic crosslinker and broken with an oxidizer at 300°F. Testing focused on crosslinker to polymer ratio analysis to effectively lower loading while maintaining sufficient performance to carry proppant at this temperature. HP/HT rheometer was used to measure viscosity, storage modulus, and fluid breaking performance. HP/HT aging cell and HP/HT see-through cell were utilized for proppant settling. FTIR, Cryo-SEM and HP/HT rheometer were also utilized to understand the interaction. Results indicate that the dual polymer fracturing fluid is able to generate stable viscosity at 300°F and 100 s-1. Results show that the dual polymer fracturing fluid can generate higher viscosity compared to the individual polymer fracturing fluid. Also, properly understanding and tuning the crosslinker to polymer ratio generates excellent performance at 20 lb/1,000 gal. The two polymers form an improved crosslinking network that enhances proppant carrying properties. It also demonstrates a clean and controlled break performance with an oxidizer. Extensive experiments were pursued to evaluate the new dual polymer system for the first time. This system exhibits a positive interaction between polysaccharide and polyacrylamide families and generates excellent rheological properties. The major benefit of using a mixed polymer system is to reduce polymer loading. Lower loading is highly desirable because it reduces material cost, eases field operation and potentially lowers damage to the fracture face, proppant pack, and formation.
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