Fiber Stiffness: An Essential Parameter of the Effectiveness of Fiber-Based Lost Circulation Materials—A CFD-DEM Numerical Investigation

IF 3.2 3区工程技术 Q1 ENGINEERING, PETROLEUM

SPE Journal Pub Date : 2023-11-01 DOI:10.2118/218377-pa

Cassian Henriques, A. Dahi Taleghani

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引用次数: 0

Abstract

Fiber materials have become an attractive choice for lost circulation material (LCM) applications recently. While there has been significant attention on the size, aspect ratio, and size distribution of fibers, the stiffness or basically the effect of their deformability on the sealing capability has not been studied rigorously. Experimental evaluations of fibers with different material properties could be a cumbersome, time-consuming, and expensive process. Most laboratory studies are limited to one or just a few different types of materials. Hence, a novel two-way-coupled computational fluid dynamics and discrete element method (CFD-DEM)-based numerical model is used to overcome this limitation and to simulate motion, collision, deformation, and finally entanglement of individual LCM fibers moving with the fluid along a fracture. Fiber stiffness is determined by the Young’s modulus, the fiber diameter, and the fiber length. Therefore, we investigate this effect in a parametric study with a focus on the impact of the length, diameter, and Young’s modulus of the fiber on their sealing capability. An in-depth analysis reveals that the bridging mechanism for fiber LCM changes with the stiffness of the fiber. Two distinct bridging mechanisms dependent on the fiber stiffness for fiber LCMs are identified. Based on the simulation results, we developed a conceptual model for the different mechanisms that fibers use for bridge initiation. It is also observed that in determining LCM effectiveness, both the fiber stiffness and the fiber dimensions go hand in hand. Stiff fibers were associated with greater maximum plugging pressures (MPPs). The effect of using a mix of soft and stiff fibers on fracture plugging effectiveness has been evaluated. The fiber LCM effectiveness as a consequence of the bending stiffness on bridging larger fractures is also investigated. lost circulation materials, fibers, fracture sealing, bridging mechanism

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纤维刚度：纤维基失重循环材料有效性的重要参数--CFD-DEM 数值研究

近来，纤维材料已成为失重循环材料（LCM）应用中的一种极具吸引力的选择。虽然人们对纤维的尺寸、长宽比和尺寸分布给予了极大的关注，但对其刚度或基本上是其变形能力对密封能力的影响还没有进行过严格的研究。对具有不同材料特性的纤维进行实验评估是一个繁琐、耗时且昂贵的过程。大多数实验室研究仅限于一种或几种不同类型的材料。因此，我们采用了一种基于计算流体动力学和离散元素法（CFD-DEM）的新型双向耦合数值模型来克服这一限制，并模拟单根 LCM 纤维随流体沿断裂移动时的运动、碰撞、变形和最终缠结。纤维刚度由杨氏模量、纤维直径和纤维长度决定。因此，我们在参数研究中调查了这一影响，重点是纤维的长度、直径和杨氏模量对其密封能力的影响。深入分析发现，纤维 LCM 的桥接机制会随着纤维刚度的变化而变化。我们确定了两种不同的桥接机制，它们取决于纤维 LCM 的纤维刚度。根据模拟结果，我们为纤维起桥的不同机制建立了一个概念模型。我们还发现，在确定 LCM 的有效性时，纤维刚度和纤维尺寸是相辅相成的。刚性纤维与更大的最大堵塞压力 (MPP) 有关。我们还评估了混合使用软纤维和硬纤维对断裂堵塞效果的影响。此外，还研究了弯曲刚度对桥接较大裂缝的纤维 LCM 效果。失重循环材料、纤维、裂缝封堵、桥接机制

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来源期刊

SPE Journal 工程技术-工程：石油

CiteScore

7.20

自引率

11.10%

发文量

229

审稿时长

4.5 months

期刊介绍： Covers theories and emerging concepts spanning all aspects of engineering for oil and gas exploration and production, including reservoir characterization, multiphase flow, drilling dynamics, well architecture, gas well deliverability, numerical simulation, enhanced oil recovery, CO2 sequestration, and benchmarking and performance indicators.