新一代自动控制注水井稳定性的出流量控制装置——以ADNOC陆上项目为例

Sultan Ibrahim Al Shemaili, A. Fawzy, E. Assreti, M. El Maghraby, M. Moradi, Prabodh Chaube, Tawheed Mohammed
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引用次数: 0

摘要

为了改善注水井的适水性,最终提高油田采收率,已经应用了几种技术。独立的被动流量控制装置或这些装置与滑套相结合已经成功地改善了井的一致性,然而,它们可能无法在具有复杂/动态特性(包括扩展/扩张裂缝或断层)的油藏中提供所需的性能,并且可能还需要干预。这主要是因为与井的其他部分相比,该特征段的注入能力不断增加,导致大部分注入流体被转移到小偷层,最终造成附近生产井的短路。新的自动注入装置通过选择性地阻塞注入到井中不断增长的裂缝中的流体,克服了这一问题。一旦达到该区域预定义的流量上限,阀门就会自动关闭。A井向B井注水已经好几年了。从调查中可以看出,该井穿过两个主要断层和另外两个特征/裂缝,其性质具有很大的不确定性。自动阀的使用被认为是控制该井水一致性的最佳解决方案。该装置最初作为普通的被动流出控制阀工作,如果通过该阀的注入流量超过设计限值,该装置将自动关闭。与井的其他部分相比,如果断层和裂缝具有高导电性,则该装置具有控制断层和裂缝的优势,并且一旦这些区域关闭,该装置可以将流体分配到井的其他部分,从而提高整体注入一致性。为了将现有的双完井改为单完井,同时考虑到断层和特征属性的巨大不确定性,研究人员进行了全面的研究,以确定最佳完井设计,以实现井的目标速率。改造后的完井包括9个带有自动阀的接头和5个带有旁路ICD阀的接头,安装在水平井段的6个隔室中,隔室中有5个膨胀封隔器。完井作业于2020年年中完成,自2020年9月以来一直在进行注入作业。井的性能结果表明,新完井成功地实现了目标速率。此外,PLT在2021年2月进行的一项调查数据显示,这些阀门成功地减少了流向断层和裂缝的流出。这可以自动实现优化的井性能,因为盗贼层对注入流体一致性的影响得到了缓解,并保持了平衡的注入分布。本文介绍了ADNOC在中东的一口注水井中早期安装阀门的结果。本文讨论了应用完井设计流程以及一些现场性能和PLT数据。
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The New Generation of Outflow Control Devices Autonomously Controlling the Conformance of Water Injection Well- A Case Study with ADNOC Onshore
Several techniques have been applied to improve the water conformance of injection wells to eventually improve field oil recovery. Standalone Passive flow control devices or these devices combined with Sliding sleeves have been successful to improve the conformance in the wells, however, they may fail to provide the required performance in the reservoirs with complex/dynamic properties including propagating/dilating fractures or faults and may also require intervention. This is mainly because the continuously increasing contrast in the injectivity of a section with the feature compared to the rest of the well causes diverting a great portion of the injected fluid into the thief zone which ultimately creates short-circuit to the nearby producer wells. The new autonomous injection device overcomes this issue by selectively choking the injection of fluid into the growing fractures crossing the well. Once a predefined upper flowrate limit is reached at the zone, the valves autonomously close. Well A has been injecting water into reservoir B for several years. It has been recognised from the surveys that the well passes through two major faults and the other two features/fractures with huge uncertainty around their properties. The use of the autonomous valve was considered the best solution to control the water conformance in this well. The device initially operates as a normal passive outflow control valve, and if the injected flowrate flowing through the valve exceeds a designed limit, the device will automatically shut off. This provides the advantage of controlling the faults and fractures in case they were highly conductive as compared to other sections of the well and also once these zones are closed, the device enables the fluid to be distributed to other sections of the well, thereby improving the overall injection conformance. A comprehensive study was performed to change the existing dual completion to a single completion and determine the optimum completion design for delivering the targeted rate for the well while taking into account the huge uncertainty around the faults and features properties. The retrofitted completion including 9 joints with Autonomous valves and 5 joints with Bypass ICD valves were installed in the horizontal section of the well in six compartments separated with five swell packers. The completion was installed in mid-2020 and the well has been on the injection since September 2020. The well performance outcomes show that new completion has successfully delivered the target rate. Also, the data from a PLT survey performed in Feb 2021 shows that the valves have successfully minimised the outflow toward the faults and fractures. This allows achieving the optimised well performance autonomously as the impacts of thief zones on the injected fluid conformance is mitigated and a balanced-prescribed injection distribution is maintained. This paper presents the results from one of the early installations of the valves in a water injection well in the Middle East for ADNOC onshore. The paper discusses the applied completion design workflow as well as some field performance and PLT data.
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