创新的封隔器解决方案,可在渗透性和衰竭地层固井时控制漏失

Jorge Vasquez, Anibal Flores, Rama Anggarawinata, Victor Hung Jie Thien, Lakmun Chan, Nur Izzah Haji Yaakub
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引用次数: 0

摘要

在渗透性、天然裂缝和枯竭地层中进行钻井和固井已经成为全球最常见的挑战之一。文莱近海油田的一家主要作业者在这些地层中也面临着类似的挑战。在这个困难的地层中,固井作业的主要目的是隔离浅层油气层。在不产生漏失的情况下实现理想的水泥顶(TOC)是主要的设计挑战。钻穿此类地层通常会导致漏失。这使得后续固井作业更具挑战性。为了最大限度地减少固井作业期间的损失,设计了一种创新的定制隔离系统,并在注入水泥浆之前立即泵入。这种定制的隔离系统不仅有助于泥浆清除和井筒清洁,还有助于减少固井过程中的漏失。在先进的液压模拟器和行业领先的计算流体动力学(CFD)软件的帮助下,对隔离剂和水泥浆的密度和流变性进行了优化。为了验证隔离系统的有效性,进行了几项实验室测试,以确定隔离系统堵塞多孔介质的能力。进行了专门的颗粒悬浮分析,以确保隔离剂设计在动态和停井期间都能保持流体系统的固体输送稳定性。这有助于避免堵塞浮子设备和尾管悬挂器的关键流道等限制条件。为了验证隔离器的设计,对地面套管、中间套管和生产套管进行了多次现场作业。对于每个作业,根据井眼状况和漏失的严重程度定制了隔离器设计。对于此类作业,最初的纯水力模拟预测了损失的可能性。在使用该定制隔离系统的固井作业中,没有漏失或漏失显著降低。这些结果证实,定制的隔离剂有助于减轻静水压力造成的漏失。此外,还根据返地流体和最终驱替压力对水泥顶部进行了验证。在2020年第三季度,首次使用这种创新的隔离系统进行了13-3/8英寸的地面套管固井作业。在水泥浆之前,将100bbls的11ppg隔离剂泵入可渗透地层。在地表观察水泥回潮。自第一次作业以来,该创新的隔离系统已在文莱海上成功进行了14次固井作业,适用于各种套管尺寸。
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Innovative Spacer Solution to Control Losses While Cementing in Permeable and Depleted Formations
Drilling and cementing across permeable, naturally fractured, and depleted formations have become some of the most common challenges across the world. A major operator in Offshore Brunei was facing similar challenges across such formations. The primary objective of the cementing job across this difficult formation was to isolate shallow hydrocarbon zones. Achieving desired top of cement (TOC) without inducing losses was the major design challenge. Drilling across such formation generally leads to loss circulation scenarios. This makes subsequent cementing operation more challenging. In order to minimize losses during the cement job, an innovative tailored spacer system was designed and pumped immediately before the cement slurry. This tailored spacer system not only helped in mud removal and wellbore cleaning but also helped to mitigate losses during cementing. Spacer and cement slurry density and rheology was optimized with the help of an advanced hydraulic simulator and industry leading computational fluid dynamics (CFD) software. To check the effectiveness of the spacer system, several laboratory tests were conducted to determine the spacer system's ability to plug a porous medium. Specialized particle suspension analysis was conducted to assure that the spacer design can maintain the fluid system's solid transport stability under both dynamic and shutdown periods. This helped to avoid plugging off restrictions such as critical flow paths in float equipment and the liner hanger. To validate the spacer design, several field jobs were executed for surface, intermediate and production casing scenarios. For each job the spacer design was tailored for the wellbore condition based on the severity of losses. For such jobs, initial purely hydraulic simulations predicted the possibility of losses. No losses or substantially reduced losses were noted for the cement jobs where this tailored spacer system was used. These results validated that the tailored spacer helped to mitigate the loss potential from the hydrostatic pressure. Top of cement was also validated based on fluids returns to surface and final displacement pressure. The first cement job using this innovative spacer system was executed for a 13-3/8inch surface casing job in Q3-2020. 100 bbls of an 11 ppg spacer was pumped across a permeable formation ahead of the cement slurry. Cement returns were observed at surface. Since the first job, 14 cement jobs using this innovative spacer system have been successfully executed in offshore Brunei for various casing sizes.
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