阿曼苏丹国南部强含水层油田油田规模聚合物开发优化

Reham Jabri, R. Mjeni, M. Gharbi, A. Alkindi
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引用次数: 0

摘要

聚合物驱已被确定为位于阿曼苏丹国南部的两个稠油油田开发的下一阶段。这些油田由强大的底部含水层驱动支撑,由于不利的流动性,导致了大量的产水。为了验证聚合物扫井的概念,设计并成功进行了现场试验。此外,由于处理返产聚合物的相关挑战,进行了一些测试,以评估聚合物对便器的影响。该油田的开发将分阶段进行,以减少资本支出,最大限度地利用现有设施,管理项目风险,同时为整体生产做出贡献。两个油田的动态建模表明,聚合物开发是可行的。模拟工作得到了现场试验的支持,该试验旨在证明聚合物波及性能、注入能力以及聚合物在强含水层中的损失。该试验通过详细的监测程序进行监测,包括压力、注入/生产速率、粘度和水质,得出了该过程中产油量增加的结论。与此同时,还进行了若干实验室和实地试验,以评估聚合物对地面设施的影响,如加热器、分离罐和实地芦苇床(湿行星)的生长。在现场试验中,通过注入聚合物可以清楚地观察到持续增加的产油量。由于聚合物、生物和水质的综合问题,注入性无法按计划保持。随后的测试包括杀菌剂注入、聚合物批次的QA/QC以及一些井增产测试,都显示了注入能力的改善。破乳剂测试降低了产生稳定乳剂的风险。实验室测试表明,在150°C以下没有观察到加热器结垢。短期和长期调查表明,水污染聚合物对湿地植物的影响是积极的,植物没有出现坏死。这是测试到背生产的聚合物浓度水平为500 ppm。这是可以实现的,因为该设施接收了过量的水,允许将回产的聚合物稀释到所需的水平。这有助于使该项目更具经济吸引力,因为它可以从整个项目的资本支出中节省约30%。建模工作建议在两个油田共钻约200个聚合物注入器,但为了管理成本并进一步降低项目风险,评估了一种优化的分阶段开发方法。采用分析和建模两种方法来确定分阶段策略。分阶段战略将从最具吸引力到最不具吸引力的地区开始,允许在承诺开发这些地区之前对这些地区进行评估。这个开发阶段的关键推动者是标准化和复制开发。因此,选择了用于聚合物制备和注射的模块化设施,其中将对第一阶段进行详细设计,然后将在其他阶段进行复制。第一阶段的发展将在中心地区进行,因为与其他地区相比,该地区对模型的反应更好。这一阶段将包括钻井25个注入器,需要两个模块化设施。在后续阶段,每两年将钻探25至30个注水井。不同的地面和地下测试为在具有强底含水层的结构中全面实施聚合物注入铺平了道路。本文讨论了阶段性和复制策略,以减轻项目风险,在进行中学习,提高项目的进度和经济效益。
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Optimizing Field Scale Polymer Development in Strong Aquifer Fields in the South of the Sultanate of Oman
Polymer flooding has been identified as the next phase of developing two heavy oil fields located in the South of the Sultanate of Oman. The fields are supported with a strong bottom aquifer drive that results in large amount of water production due to the adverse mobility. In order to prove the concept of polymer sweep, a field trial was designed and conducted successfully in the field. Moreover, due to the challenges associated to handling back produced polymer number of tests were conducted to assess the impact of polymer on facilitates. Development of the field will take place in a phased manner in order to reduce the capex exposure, maximize the utilization of the existing facility and managing project risks while contributing to the overall production. Dynamic modeling of both fields showed that polymer development is feasible. The modeling work was supported by a field trial that was designed to prove: polymer sweep performance, injectivity, as well as polymer losses to the strong water aquifer. This trial was monitored with detailed surveillance program including pressure, injection/production rates, viscosity and water quality, which concluded incremental oil gain from the process. In parallel, a number of laboratory and field tests were performed to assess the impact of polymer on the surface facilities such as the heater, separation tanks and the growth of the reed beds - wet planets- in the field. Sustained incremental oil gain was clearly observed from polymer injection in the field trial. Injectivity could not be maintained as planned, due to a combination of polymer, biological and water quality issues. Later tests including biocide injection and QA/QC of polymer batches as well as some well stimulation did show improved injectivity profiles. Demulsifier tests mitigated the risk of creating stable emulsions. Laboratory tests indicated no heater fouling observed below 150°C. Short and long term investigation into the impact of water- contaminated polymer on plants in the wet lands was positive with the plants showing no necrosis. This was tested up to back produce polymer concentration levels of 500 ppm. Which is achievable given the excessive amount of water received at the facility allowing the dilution of back produced polymer to the required level. This helped in making the project more economically attractive as it results in a saving of around 30% from the overall project Capex. The modeling exercise proposed drilling of around 200 polymer injectors across both fields, but in order to manage costs and further reduce project risks an optimised phased development approach was evaluated. Both Analytical and modeling approach were used to identify the phasing strategy. The phasing strategy will start with the most attractive to least attractive areas allowing for appraisal these areas prior to committing to their development. The key enabler for phasing of this development is by standardizing and replicating the development. Hence, modular facility for polymer preparation and injection was selected, in which a detailed design will be conducted for the first phase then it will be replicated for the other upcoming phases. Phase-1 of the development will be in the central area as it is has a better response from the model compared to the other areas. This phase will include the drilling of 25 injectors and it will require two modular facilities. 25 to 30 injectors will subsequently be drilled every 2 years for the follow up phases. The different surface and subsurface tests paved the way for a full field implementation of polymer injection in structures with strong bottom water aquifer. The paper discusses the phasing and replication strategy to mitigate project risks, learn on the go and improve the project’s schedules and economics.
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