Efficient placement technology of proppants based on structural stabilizers

IF 7 Q1 ENERGY & FUELS Petroleum Exploration and Development Pub Date : 2024-06-01 DOI:10.1016/S1876-3804(24)60499-4
Jianchun GUO , Shan REN , Shaobin ZHANG , Su DIAO , Yang LU , Tao ZHANG
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Abstract

Fiber is highly escapable in conventional slickwater, making it difficult to form fiber-proppant agglomerate with proppant and exhibit limited effectiveness. To solve these problems, a novel structure stabilizer (SS) is developed. Through microscopic structural observations and performance evaluations in indoor experiments, the mechanism of proppant placement under the action of the SS and the effects of the SS on proppant placement dimensions and fracture conductivity were elucidated. The SS facilitates the formation of robust fiber-proppant agglomerates by polymer, fiber, and quartz sand. Compared to bare proppants, these agglomerates exhibit reduced density, increased volume, and enlarged contact area with the fluid during settlement, leading to heightened buoyancy and drag forces, ultimately resulting in slower settling velocities and enhanced transportability into deeper regions of the fracture. Co-injecting the fiber and the SS alongside the proppant into the reservoir effectively reduces the fiber escape rate, increases the proppant volume in the slickwater, and boosts the proppant placement height, conveyance distance and fracture conductivity, while also decreasing the proppant backflow. Experimental results indicate an optimal SS mass fraction of 0.3%. The application of this SS in over 80 wells targeting tight gas, shale oil, and shale gas reservoirs has substantiated its strong adaptability and general suitability for meeting the production enhancement, cost reduction, and sand control requirements of such wells.

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基于结构稳定剂的支撑剂高效铺放技术
纤维在传统的浮油中极易逸出,因此很难与支撑剂形成纤维-支撑剂团聚体,而且效果有限。为了解决这些问题,我们开发了一种新型结构稳定剂(SS)。通过微观结构观察和室内实验性能评估,阐明了支撑剂在 SS 作用下的铺放机理以及 SS 对支撑剂铺放尺寸和压裂传导性的影响。SS 有利于聚合物、纤维和石英砂形成坚固的纤维-支撑剂团聚体。与裸支撑剂相比,这些团聚体在沉降过程中密度降低、体积增大、与流体的接触面积增大,从而产生更大的浮力和阻力,最终导致沉降速度减慢,并增强了向压裂深部区域的输送能力。将纤维和 SS 与支撑剂一起注入储层,可有效降低纤维逸出率,增加滑油水中的支撑剂体积,提高支撑剂的投放高度、输送距离和压裂传导性,同时减少支撑剂回流。实验结果表明,最佳 SS 质量分数为 0.3%。在 80 多口以致密气、页岩油和页岩气藏为目标的油井中的应用证明,这种固液法具有很强的适应性和普遍适用性,可以满足此类油井的增产、降低成本和防砂要求。
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CiteScore
11.50
自引率
0.00%
发文量
473
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