Novel Analytical Solution and Type-Curves for Lost-Circulation Diagnostics of Drilling Mud in Fractured Formation

R. Albattat, H. Hoteit
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引用次数: 0

Abstract

Loss of circulation is a major problem that often causes interruption to drilling operations, and reduction in efficiency. This problem often occurs when the drilled wellbore encounters a high permeable formation such as faults or fractures, leading to total or partial leakage of the drilling fluids. In this work, we present a novel semi-analytical solution and type-curves that offer a quick and accurate diagnostic tool to assess the lost-circulation of Herschel-Bulkley fluids in fractured media. Based on the pressure and mud loss trends, the tool can estimate the effective fracture conductivity, the cumulative mud-loss volume, and the leakage period. The behavior of lost-circulation into fractured formation can be assessed using analytical methods that can be deployed to perform flow diagnostics, such as the rate of fluid leakage and the associated fracture hydraulic properties. In this study, we develop a new semi-analytical method to quantify the leakage of drilling fluid flow into fractures. The developed model is applicable for non-Newtonian fluids with exhibiting yield-power-law, including shear thickening and thinning, and Bingham plastic fluids. We propose new dimensionless groups and generate novel dual type-curves, which circumvent the non-uniqueness issues in trend matching of type-curves. We use numerical simulations based on finite-elements to verify the accuracy of the proposed solution, and compare it with existing analytical solutions from the literature. Based on the proposed semi-analytical solution, we propose new dimensionless groups and generate type-curves to describe the dimensionless mud-loss volume versus the dimensionless time. To address the non-uniqueness matching issue, we propose, for the first time, complimentary derivative-based type-curves. Both type-curve sets are used in a dual trend matching, which significantly reduced the non-uniqueness issue that is typically encountered in type-curves. We use data for lost circulation from a field case to show the applicability of the proposed method. We apply the semi-analytical solver, combined with Monte-Carlo simulations, to perform a sensitivity study to assess the uncertainty of various fluid and subsurface parameters, including the hydraulic property of the fracture and the probabilistic prediction of the rate of mud leakage into the formation. The proposed approach is based on a novel semi-analytical solution and type-curves to model the flow behavior of Herschel-Bulkley fluids into fractured reservoirs, which can be used as a quick diagnostic tool to evaluate lost-circulation in drilling operations.
裂缝地层钻井液漏失诊断的新型解析解和类型曲线
漏失是导致钻井作业中断和效率降低的主要问题。当钻出的井筒遇到断层或裂缝等高渗透性地层,导致钻井液全部或部分泄漏时,就会出现这个问题。在这项工作中,我们提出了一种新的半解析解和类型曲线,为评估压裂介质中Herschel-Bulkley流体的漏失提供了一种快速准确的诊断工具。根据压力和泥浆损失趋势,该工具可以估计有效裂缝导流能力、累积泥浆损失量和泄漏周期。可以使用分析方法来评估压裂地层的漏失行为,这些分析方法可以用于进行流体诊断,例如流体泄漏速率和相关的裂缝水力特性。在这项研究中,我们开发了一种新的半解析方法来量化钻井液流入裂缝的泄漏。所建立的模型适用于具有屈服幂律的非牛顿流体,包括剪切增稠和变薄,以及Bingham塑性流体。我们提出了新的无量纲群,并生成了新的对偶型曲线,解决了型曲线趋势匹配中的非唯一性问题。我们使用基于有限元的数值模拟来验证所提出的解的准确性,并将其与文献中现有的解析解进行比较。基于所提出的半解析解,我们提出了新的无量纲群,并生成了描述无量纲失泥体积与无量纲时间的类型曲线。为了解决非唯一性匹配问题,我们首次提出了互补导数型曲线。在双趋势匹配中使用了两个类型曲线集,这大大减少了类型曲线中通常遇到的非唯一性问题。我们使用了一个现场案例的漏失数据来证明所提出方法的适用性。我们将半解析求解器与蒙特卡罗模拟相结合,进行敏感性研究,以评估各种流体和地下参数的不确定性,包括裂缝的水力特性和泥浆泄漏到地层中的概率预测。该方法基于一种新颖的半解析解和类型曲线来模拟Herschel-Bulkley流体在裂缝性储层中的流动行为,可作为钻井作业中评估漏失的快速诊断工具。
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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