Numerical Modelling of Hydraulic Fracturing in Cohesionless Sand: Validation Against Laboratory Experiments

Journal of Canadian Petroleum Technology Pub Date : 2015-12-01 DOI:10.2118/178439-PA

S. Taghipoor, A. Nouri, D. Chan

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引用次数: 5

Abstract

Summary In this paper, a new hydraulic-fracturing model is introduced for cohesionless sand, which is also applicable to weak sandstone for- mations with high permeability and low shear strength. Phenomena such as shear-band development and shear-enhanced permeability are of paramount importance during hydraulic fracturing of cohesionless sand or weak sandstones, which make the fracturing response quite different from what it is conventionally believed to be in competent rocks. The smeared approach in simulating hydraulic fracturing has been implemented in the proposed model within the continuum mechanics framework. Both matrix and fracture ﬂow have been considered in this model. Tensile- and shear-fracture development and their ﬂuid ﬂow were simulated. The cubic law and Touhidi-Baghi-ni’s shear-permeability model (Touhidi-Baghini 1998) were used to capture the permeability evolution and to model ﬂow in tensile and shear fractures, respectively. Shear fracturing of geomaterials involves intense localization of deformation and strain softening, which is a discontinuous phenomenon, resulting in mesh dependency of the results in the continuum model. The fracture-energy-reg-ularization method was used in this model to reduce the mesh-size dependency of the energy dissipated during fracture propagation. The smeared-fracture approach has been validated against lab- oratory hydraulic-fracturing experiments with reasonable agreement. Consistent with the experiments, the results of the numerical model indicate that tensile fractures are formed in a very small area around the injection point despite the application of high injection pressure compared with the minimum boundary stress. It is found that shear fracturing and shear-permeability evolution are the most important mechanisms that inﬂuence and control the fracturing response. The dominant fracturing mechanism is found to be governed by the high permeability and low shear strength of the material.

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无黏性砂土水力压裂数值模拟:实验室实验验证

本文介绍了一种新的无黏性砂岩水力压裂模型，该模型同样适用于高渗透低抗剪强度的软弱砂岩。剪切带发育和剪切增强渗透率等现象在无黏性砂岩或弱砂岩水力压裂过程中至关重要，这使得压裂响应与常规认为的在能力岩中的压裂响应大不相同。该模型在连续介质力学框架下实现了模拟水力压裂的模糊方法。该模型同时考虑了基质流动和裂缝流动。模拟了拉伸和剪切裂缝发育及其流体流动。利用立方定律和Touhidi-Baghi-ni剪切渗透率模型(Touhidi-Baghini 1998)分别捕捉渗透率演化和模拟拉伸裂缝和剪切裂缝中的流动。岩土材料的剪切破裂涉及到强烈的局部化变形和应变软化，这是一种不连续现象，导致连续体模型中结果的网格依赖。该模型采用裂缝-能量正则化方法，降低了裂缝扩展过程中能量耗散对网格尺寸的依赖性。通过室内水力压裂实验验证了该方法的有效性，并取得了较好的一致性。数值模型的结果与实验结果一致，表明尽管注入压力比最小边界应力高，但在注入点周围很小的区域内仍会形成拉伸裂缝。研究发现，剪切致裂和剪切-渗透演化是影响和控制压裂响应的最重要机制。发现主要的断裂机制是由材料的高渗透性和低抗剪强度决定的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Canadian Petroleum Technology 工程技术-工程：化工

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审稿时长

11.4 months