高压高温致密气藏多级压裂井再射孔提高产能的实例研究

IF 16.4 1区 化学 Q1 CHEMISTRY, MULTIDISCIPLINARY
Ryosuke Kidogawa, N. Yoshida, K. Fuse, Yuta Morimoto, K. Takatsu, Keisuke Yamamura
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引用次数: 4

摘要

在长期生产过程中,多级压裂气井的产能可能会因导电性受损和非达西流动而降低。这种退化通过流收敛到短穿孔间隔而明显,而确定修复的退化阶段具有挑战性。此外,在高压/高温(HP/HT)环境下,补救措施可能是昂贵的。一个现场案例表明,通过对具有多速率生产测井(PL)结果的目标进行优先级排序,再射孔作为一种经济高效的方法成功应用,可以缓解流量收敛。本工作采用数值模拟和现场执行的方法,对日本陆上高压/高温火山气藏中一口采用六阶段压裂处理的井进行了理论研究。在超过15年的生产过程中,人们怀疑表观电导率降低,并且与流收敛到短射孔层段相关的非达西流效应使其显著。多速率PL用于通过量化瞬态流量(FAF)测试下每个阶段的流入性能关系(IPR)来识别受损阶段。受损阶段重新射孔,用钢丝绳输送的射孔器增加射孔间隔。使用作业前后和作业后PL的压力累积(PBU)测试来验证生产力的提高。根据进行的多速率PL的结果,确定了再穿孔的目标区域并确定了优先顺序。绘制了阶段IPR,通过IPR的形状和/或随着地表速率的增加而减少的流入贡献,在三个阶段中确定了相对较大的非达西效应。此外,温度日志显示第四阶段底部的温度变化剧烈;裂缝可能在射孔层段下方扩展。使用根据估计阶段IPR校准的数值模型来估计产量增量的范围。根据计划的再射孔计划,估计增量在15%至30%的范围内,而其大小取决于新射孔和现有裂缝之间的连接。之后,进行了重新穿孔工作,并确认在生产1个月后,在相同的井口压力下,气体速率增加了26%。术后PL在再穿孔后3个月进行。井IPR得到改善,意味着非达西效应的减少。PBU测试结果也表明皮肤因子降低。用作业后PL重新绘制了阶段IPR,它们表明在压裂处理期间出现筛选的两个阶段和怀疑存在显著非达西效应的一个阶段有明显的改进。本文的工作流程和策略可以以一种具有成本效益的方式应用于长期生产中射孔间隔短、表观电导率受损的多级压裂气井的产能恢复。特别是,解释的结果表明,在压裂处理过程中出现筛选的阶段,所提出的方法对提高生产力是有效的。此外,还讨论了仔细的PL测试设计的重要性,因为它们是成功的关键。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Productivity Improvement by Reperforation of Multistage-Fractured Wells in High-Pressure/High-Temperature Tight Gas Reservoirs: A Case History
Productivity of multistage-fractured gas wells is possibly degraded by conductivity impairments and non-Darcy flow during long-term production. Such degradations are pronounced by flow convergence to short perforated intervals, while it is challenging to identify degraded stages for remediation. Moreover, remedial actions can be expensive under a high-pressure/high-temperature (HP/HT) environment. A field case demonstrates successful application of reperforation as a cost-effective way to mitigate the flow convergence by prioritizing targets with multirate production-logging (PL) results. This work presents theoretical investigations using numerical simulations and field execution of reperforation for a well with six-stage fracturing treatments in a HP/HT volcanic gas reservoir onshore Japan. Apparent conductivity reduction was suspected during more than 15 years of production, and it was pronounced by non-Darcy flow effects associated with flow convergence to short perforated intervals. Multirate PL was used to identify impaired stages by quantifying the inflow-performance relationship (IPR) of each stage under transient flow-after-flow (FAF) testing. The impaired stages were reperforated, adding perforation intervals with wireline-conveyed perforators. Pressure-buildup (PBU) tests before and after the job and post-job PL were used to validate productivity improvements. Target zones for reperforations were identified and prioritized with results of the multirate PL conducted. The stage IPRs were drawn, and relatively large non-Darcy effects were identified in three stages by shapes of the IPRs and/or decreasing inflow contributions as the surface rate increased. Also, a temperature log showed steep temperature change at the bottom of the fourth stage; the fracture might propagate below the perforated interval. Ranges of production increment were estimated using a numerical model calibrated against the estimated stage IPRs. The estimated increment was in the range of 15 to 30% with the planned reperforation program, while its magnitude depended on the connection between new perforations and existing fractures. Afterward, the reperforation job was performed and the gas rate was confirmed to be increased by 26% with the same wellhead pressure after 1 month of production. The post-job PL was conducted 3 months after the reperforation. The well IPR was improved, implying reduction of the non-Darcy effects. Results of PBU tests also indicated reduction of skin factor. The stage IPRs were redrawn with the post-job PL, and they suggested clear improvements in two stages where screenout occurred during fracturing treatments and a stage where significant non-Darcy effect was suspected. The workflow and strategy in this paper can be applied for productivity restoration in a cost-effective way to multistage-fractured gas wells with short perforated intervals and impaired apparent conductivity during long-term production. Especially, the interpreted results suggested effectiveness of the proposed approach for productivity improvement in stages where screenout occurs during fracturing treatments. Moreover, lessons learned on the importance of careful test designs for PL were discussed because they are keys for success.
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来源期刊
Accounts of Chemical Research
Accounts of Chemical Research 化学-化学综合
CiteScore
31.40
自引率
1.10%
发文量
312
审稿时长
2 months
期刊介绍: Accounts of Chemical Research presents short, concise and critical articles offering easy-to-read overviews of basic research and applications in all areas of chemistry and biochemistry. These short reviews focus on research from the author’s own laboratory and are designed to teach the reader about a research project. In addition, Accounts of Chemical Research publishes commentaries that give an informed opinion on a current research problem. Special Issues online are devoted to a single topic of unusual activity and significance. Accounts of Chemical Research replaces the traditional article abstract with an article "Conspectus." These entries synopsize the research affording the reader a closer look at the content and significance of an article. Through this provision of a more detailed description of the article contents, the Conspectus enhances the article's discoverability by search engines and the exposure for the research.
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