前进一个阶段还是后退两个阶段:我们在治疗什么?水力压裂过程中套管内部腐蚀的识别——基于超声波和光纤诊断的Montney案例研究

IF 1.3 4区 工程技术 Q3 ENGINEERING, PETROLEUM SPE Drilling & Completion Pub Date : 2020-11-01 DOI:10.2118/201734-pa
M. White, K. Friehauf, D. Cramer, J. Constantine, Junjing Zhang, S. Schmidt, J. Long, Paul Mislan, J. Spencer, P. Meier, E. Davis
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引用次数: 4

摘要

非常规储层的塞射孔(塞射孔)多级水力压裂完井依赖于与前一阶段的完全水力隔离,以确保有效处理活跃阶段。未能隔离阶段可能是由于堵塞器部分设置、堵塞器设置在井筒碎片或变形套管中、堵塞器的压力/温度额定值不合格等原因造成的。本文介绍了一个案例研究和现场实例,其中在水力压裂过程中,可溶性压裂(frac)塞的设置深度发生了意外的套管侵蚀,随后导致级间隔离损失。设计了一个12口井、四层立方体先导器,该先导器带有永久性光纤电缆,用于收集分布式声学传感(DAS)、分布式温度传感(DTS)和分布式应变传感(DSS)数据以及井下压力计,用于深入了解开发情况和未来完井优化。对电缆进行了测绘,定向射孔技术沿着井筒将进入孔与光纤相对放置,在射孔操作过程中没有观察到通信中断。然而,在所有四口装有仪器的水平井的一个或多个阶段的水力压裂操作中,光纤信号都丢失了。实时DAS/DTS分析表明,纤维断裂始终发生在该阶段的最低射孔簇下方,处于或非常接近压裂塞设置深度。还进行了降压试验,结果显示有效治疗面积明显扩大。基于这一观察结果,部署了压裂后井下成像工具来调查潜在的套管和射孔侵蚀。井下成像数据清楚地表明,套管在几个位置受到严重侵蚀。对塞子设计部件的损坏进行的额外询问表明,损坏总是发生在塞子密封元件附近。通过综合DAS/DTS、降压测试和超声波成像的分析,确定压裂塞旁路在塞组位置造成套管完整性损失。套管完整性损失导致多条光纤电缆断裂,并降低了将泥浆均匀分布到处理集群中的能力。光纤数据分析显示,50%的外径较大的可溶解压裂插塞具有旁路,而外径较小的高膨胀可溶解插塞具有100%旁路。为了建立关键模式并确定影响刺激有效性的关键变量,重要的是获得几个不同的诊断数据集,并使用所有可用信息进行综合评估。这项研究还强调了运营商和制造商合作设计压裂塞并使其符合实际井下条件的必要性,特别是在存在潜在套管变形问题的地区。需要进行行业创新,使压裂作业能够通过变形套管继续进行。这包括先进的设备、工具和技术,用于塞-塞和其他多级完井方法。
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One Stage Forward or Two Stages Back: What Are We Treating? Identification of Internal Casing Erosion during Hydraulic Fracturing—A Montney Case Study Using Ultrasonic and Fiber-Optic Diagnostics
Plug-and-perforation (plug-and-perf) multistage hydraulic fracturing completions in unconventional reservoirs rely on complete hydraulic isolation from the previous stage to ensure effective treatment of the active stage. Failure to isolate stages can be a result of partially set plugs, plugs set in wellbore debris or deformed casing, unqualified pressure/temperature rating of plugs, and so on. This paper presents a case study with field examples in which unexpected casing erosion occurred at the setting depths of the dissolvable fracturing (frac) plugs during hydraulic fracturing and subsequently resulted in loss of interstage isolation. A 12-well, four-layer, cube pilot was designed with permanent fiber-optic cable to collect distributed acoustic sensing (DAS), distributed temperature sensing (DTS), and distributed strain sensing (DSS) data as well as downhole pressure gauges for development insight and future completion optimization. The cable was mapped, and oriented perforation techniques placed entry holes opposite the fiber along the wellbore, and no loss of communication was observed during perforating operations. However, fiber-optic signal was lost during hydraulic fracturing operations on one or more stages in all four instrumented horizontal wells. Real-time DAS/DTS analysis indicated the fiber breaks were consistently occurring below the lowermost perforation cluster in the stage, at or very near the frac plug setting depth. Step-down tests were also performed and showed significantly enlarged effective treating area. Based on this observation, post-frac downhole imaging tools were deployed to investigate potential casing and perforation erosion. Downhole imaging data clearly showed the casing was severely eroded at several locations. Additional interrogation of the damage with respect to plug design components indicated that damage always occurred near the plug sealing element. By integrating the analysis of DAS/DTS, step-down tests, and ultrasonic imaging, it was determined that the frac plug bypass was creating a loss of casing integrity at the plug set location. Casing integrity loss resulted in multiple fiber-optic cable breaks and lowered the ability to evenly distribute slurry into treatment clusters. Fiber-optic data analysis showed that 50% of the larger outer diameter (OD) dissolvable frac plugs had bypass compared to 100% bypass for the smaller OD high-expansion, dissolvable plugs. To establish key patterns and identify critical variables that influence stimulation effectiveness, it is important to obtain several different diagnostic data sets and perform an integrated evaluation using all available information. This study also reinforces the need for operators and manufacturers to work together to design and qualify frac plugs against realistic downhole conditions, particularly in areas with potential casing deformation issues. Industry innovation is required to enable fracturing operations to continue through deformed casing. This includes advancing equipment, tools, and techniques for plug-and-perf and other multistage completion methods.
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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.
期刊最新文献
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