Quantifying Erosion of Downhole Solids Control Equipment during Openhole, Multistage Fracturing

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM
A. Dikshit, G. Woiceshyn, V. Agnihotri, G. Chochua, M. Noor
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引用次数: 4

Abstract

Proppant flowback from hydraulic fracturing is widespread and costly due to erosion and/or blockage of producing hydrocarbons as proppant may accumulate downhole. Several strategies have been applied to avoid or minimize proppant flowback, such as treatment optimization to maximize pack stability, resin-coated proppant, limiting drawdown, or letting it flow to deal with the consequences later. Another strategy to avoid proppant flowback is to install sand control equipment integrated into a sliding sleeve device (SSD) as part of the completion string. Although the presence of sand control equipment can mitigate the problem, it raises concern about erosion during fracturing. Although some installations have been successful, one is known to have experienced sand control failure. This study aimed to understand the effect of hydraulic fracturing on the erosion of completion equipment with an objective of improving the design to, as much as possible, prevent erosion failure. Computational fluid dynamics (CFD) was used to evaluate the root cause and identify more robust design solutions. The first step was to identify the most probable causes of sand control failure during multistage fracturing (MSF) in openhole (OH) horizontals. The as-is completion was then modeled, along with the screen, SSD, fracturing port, and OH isolation packer. Because the fracture location between two packers is unknown, and the fracturing port was located between multiple screen/SSD assemblies, annular flow across the assembly in both directions was considered. State-of-the-art CFD simulations were then performed on the installed design using actual flow conditions (rates, slurry properties, treatment time) from the failed installation. A new quasidynamic mesh (QDM) methodology was developed, which yielded more realistic (albeit still conservative) erosion-depth predictions. The results revealed areas for improving the design of key components of the 10-ksi-rated system, and CFD was rerun to confirm erosion resistance targets. Design modifications were implemented, and improved products were then manufactured and field tested. For a new 15-ksi design, particle–particle interaction was added to the CFD analysis. The results of the CFD analysis and field test are presented herein.
量化裸眼多级压裂过程中井下固体控制设备的侵蚀
由于支撑剂可能在井下积聚,从而对生产碳氢化合物造成侵蚀和/或堵塞,因此水力压裂产生的支撑剂返排广泛且成本高昂。已经采用了几种策略来避免或最大限度地减少支撑剂回流,例如优化处理以最大限度地提高充填稳定性、树脂涂层支撑剂、限制压降或让其流动以处理后续后果。避免支撑剂返排的另一种策略是将防砂设备安装到滑动套管装置(SSD)中,作为完井管柱的一部分。尽管防砂设备的存在可以缓解这个问题,但它引发了人们对压裂过程中侵蚀的担忧。尽管一些装置已经成功,但已知有一个装置出现了防砂故障。本研究旨在了解水力压裂对完井设备腐蚀的影响,目的是改进设计,尽可能防止腐蚀失效。计算流体动力学(CFD)用于评估根本原因并确定更稳健的设计解决方案。第一步是确定裸眼(OH)水平多级压裂(MSF)期间防砂失效的最可能原因。然后对原状完井以及筛网、SSD、压裂口和OH隔离封隔器进行建模。由于两个封隔器之间的裂缝位置未知,且压裂口位于多个滤网/SSD组件之间,因此考虑了沿两个方向穿过组件的环形流。然后,使用故障安装的实际流动条件(速率、浆料特性、处理时间),对安装的设计进行最先进的CFD模拟。开发了一种新的准动态网格(QDM)方法,该方法产生了更现实(尽管仍然保守)的侵蚀深度预测。结果揭示了改进10ksi额定系统关键部件设计的领域,并重新运行CFD以确认抗侵蚀目标。进行了设计修改,然后制造了改进的产品并进行了现场测试。对于新的15ksi设计,CFD分析中增加了颗粒-颗粒相互作用。本文给出了CFD分析和现场试验的结果。
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
SPE Drilling & Completion
SPE Drilling & Completion 工程技术-工程:石油
CiteScore
4.20
自引率
7.10%
发文量
29
审稿时长
6-12 weeks
期刊介绍: Covers horizontal and directional drilling, drilling fluids, bit technology, sand control, perforating, cementing, well control, completions and drilling operations.
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