持续套管压力的井下环空隔离解决方案——特立尼达案例研究

J. Olsen, Wayne Hosein, T. Ringe, J. Friedli
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引用次数: 0

摘要

在修井作业中使用的井下环空屏障(DAB)系统可以纠正井生命周期中的完整性和一致性控制问题,以安全和经济的方式延长生产周期。这些新兴的电缆技术在物流、质量控制和工程方面面临着独特的挑战,但也可以为非钻机干预领域的难题提供解决方案,具有高性价比。本文将回顾一次成功的修井作业,该作业是在特立尼达w.i.海上完成的,在一口气井中出现了长期持续套管压力(SCP)。期望的最终状态是a -环空在0 psi的SCP下,这将使油井恢复到安全状态,并允许计划的基础设施项目继续进行。作业目标是通过向环空注入环氧树脂,形成360度的压力屏障,将套管环空压力从源头隔离开来。这个项目可以分为三个主要部分。论文和演示将介绍每个部分的具体挑战、经验和成果:陆上环氧树脂和工具准备每次井下环空隔离作业都使用定制配方环氧树脂,以适应计划的物流时间和预期的井底条件。环氧树脂配方和混合工艺的质量控制以及混合后批次的温度控制是最终环氧树脂塞密封性能的关键。•环氧树脂实验室和搅拌站被拆除,空运,并在特立尼达附近的现场作业港口重建。特殊绝缘的海上CCU用于运输和容纳填充的环氧罐,同时保持低温要求(接近0℃,长达30天)。•井下系统(锚定、冲程、水力测试、射孔和注入)与电缆系统(传输、遥测、电力)的构建和系统集成测试(SIT)。采用DAB系统的目的是在一次起下钻中完成多个作业,包括射孔和高压环氧注入,并具有精确的位置控制和监测。这是通过多功能模块化工具实现的。作业是动态设计的,并且根据井的响应来实施突发事件。在A环空深处放置多个环氧环空塞,并进行高压注入。利用先进的环空地面监测技术和PvT分析,在整个作业过程中记录了环空压力形成的精确评估。一旦满足了项目标准,操作就成功地结束了。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Downhole Annular Barrier Solution for Sustained Casing Pressure - Trinidad Case Study
Downhole Annular Barrier (DAB) systems employed in intervention can correct integrity and conformance control issues during well lifecycle, extending the productive term in a safe and costeffective manner. These emergent wireline technologies come with unique challenges for logistics, quality control, and engineering, but can also provide solutions to difficult problems, with high value to spend ratio, in the non-rig intervention sector. The paper will review one such successful intervention, completed offshore Trinidad W.I., in a gas well presenting long term Sustained Casing Pressure (SCP). The desired end state of the well was A-Annulus at 0 psi SCP, which would return the well to a safe state and permit a planned infrastructure project to move ahead. Operational objective was isolation of the casing annulus pressure from the source by injecting epoxy into the annular space at depth, forming a 360-degree pressure barrier. The project can be broken down into three main sections. The paper and presentation will address each section with its specific challenges, learnings, and outcomes: Onshore Epoxy and Tool Preparation Each Downhole Annular Barrier job employs a custom recipe epoxy suited to the planned logistics timing and expected bottomhole conditions. Quality control of the epoxy recipe and mixing process as well as temperature control of the batch after mixing is key to the sealing properties of the final epoxy plug. • An Epoxy Lab and Mixing Station was dismantled, air freighted, and reconstituted in Trinidad near to the field operations port. Special insulated offshore CCU were built to transport and contain filled epoxy canisters while maintaining low temperature requirements (near to 0 deg C for up to 30 days). • Build and System Integration Testing (SIT) of the downhole system (anchoring, stroking, hydraulic testing, perforation, and injection) with the electric line system (conveyance, telemetry, power). Offshore Job Execution The DAB system employed is designed to complete multiple operations in a single trip into the well, including perforating and high-pressure epoxy injection, with precise position control and monitoring. This is made possible with the multi-function modular tool. The operation was dynamic by design and contingencies were implemented based on the well response. Multiple epoxy annular plugs were placed into the A Annulus at depth, with high pressure injection. Well Response and Assessment Utilizing advanced annular surface monitoring technology and PvT analysis, precise assessment of the annulus pressure build was recorded throughout the operation. Once the project criteria were met, the operation was successfully concluded.
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