678马来西亚海上轻度超压油藏多产层深层气井完井设计与作业解决方案的挑战

Hazirah Abdul Uloom, Asba Madzidah Abu Bakar, M. Hussain, F. Tusimin, Z. R. M. Ghazali, M. S. Salih, M. F. A. Rasid, Sunanda Magna Bela, L. Riyanto, M. Othman, Syazwan A Ghani, N. A. A. Fadzil
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Dedicated zonal sampling plan to be performed if the commingle zone (total) mercury reading was recorded to be above the threshold limit, and that zones will be shut off to preserve the surface facilities.\n Opportunity was grabbed to optimize number of wells by completing both shallow and intermediate sections in a single selective completion to maximize the project value. However, this combination will lead to major challenges during operation due to the huge difference in reservoir pressure and permeability contrast in each perforated reservoir as the required overbalanced pressure of completion brine for shallow reservoir is much lesser than the requirement for the mildly overpressure intermediate reservoir. Thus, a potential risk of severe losses and well control is present at shallow reservoir. 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引用次数: 0

摘要

根据2017年第一次开发活动的生产数据,在一年的生产中,产气井的CO2和H2S污染读数分别从3%增加到10%,从3ppm增加到16ppm。这些发现引发了2019年开发活动优化策略的重新审视,包括材料选择、井数、储层目标和完井设计。因此,油管上部的材料升级为HP1-13CR,最高可达10,000 ft-MDDF(英尺测量深度的钻井平台),以避免由于静地不受干扰的温度低于80℃而产生的SSC风险,但根据2017年的活动,深层油管的材料仍为13CR-L80。此外,根据2018年8月进行的汞测绘工作,观察到第一次活动的汞含量高于中间水库的阈值限制。由于地面设施没有安装除汞系统,因此在2019年的测试过程中,需要密切监测井中的汞读数,以便在记录的污染物读数过高时采取适当的措施。如果记录到混合区(总)汞读数高于阈值限制,将执行专门的分区采样计划,并关闭该区域以保护地面设施。通过在一次选择性完井中完成浅段和中间段,优化井数,以最大化项目价值。然而,由于每个射孔油藏的储层压力和渗透率对比差异巨大,这种组合在作业过程中会带来重大挑战,因为浅层油藏所需的完井盐水过平衡压力远低于中度超压油藏的要求。因此,浅层油藏存在严重漏失和井控的潜在风险。为了降低这种风险,在射孔枪发射之前,在TCP(油管输送射孔)底部钻具组合中预先定位了漏失循环材料,以便在发生漏失时进行自固化。在第一次开发过程中,完井油管分两个阶段下入井中。下部完井通过钻杆下入,在下部完井油管和砾石封隔器之间使用降滤失装置对射孔区域进行保护。然后下入上部完井油管,并与下部完井封隔器连接。该方法用于缓解流体漏失,并确保油管可以安全地下入到预期的最终深度。然而,根据第一次作业的实际性能和损失率数据,对第二次作业的完井设计进行了优化,并进行了单级部署。由于浅层和中层储层位于多个生产区域,并且安装了5个SSD(滑动侧门),因此由于在深井中存在坐封油管塞的风险,因此放弃了坐封封隔器的钢丝绳选择。泵出桥塞被认为是一种选择,但由于高静水压力而放弃。封隔器坐封压力与桥塞剪切压力太接近。因此,采用了一种自动消失的桥塞,因为它不需要任何钢丝干预,而且可以通过压力循环破裂。采用这种方法,可以消除桥塞过早破裂的风险。本文将详细讨论上述每个挑战,以及在选择最佳解决方案之前,在整个评估和选择过程中进行的详细计算,因为这些优化节省了近三天的钻机时间,降低了2.6%的井成本,并且所需的井数被优化为3口而不是4口。此外,通过选择合适的油管材料,消除产汞超过上述阈值限制的风险,可以提高油井的生产寿命。
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678 Challenges of Well Completion Design & Operation Solutions for Deep Gas Well with Multiple Producing Zone in Mildly Overpressured Reservoirs at Offshore Malaysia
Based on the production data from first development campaign in 2017, contamination reading of CO2 and H2S from gas production wells were observed increasing from 3% to 10% and from 3ppm to 16ppm respectively within one year production. These findings have triggered the revisit in 2019 development campaign optimization strategy in terms of material selection, number of wells, reservoir targets, and completion design. Thus, tubing material was upgraded to HP1-13CR for the upper part of tubing up to 10,000 ft-MDDF (feet measure depth drilling rig floor) to avoid SSC risk due to the geostatic undisturbed temperature is less than 80 deg C, however the material of deeper tubing remains as 13CR-L80 as per 2017 campaign. Moreover, the mercury content from first campaign was observed to be above threshold limit from intermediate reservoir based on mercury mapping exercise done in August 2018.As the mercury removal system is not incorporated in the surface facilities, the mercury reading from the well in the 2019 campaign need a close monitoring during well testing so that appropriate action can be taken in case the recorded contaminant reading is high. Dedicated zonal sampling plan to be performed if the commingle zone (total) mercury reading was recorded to be above the threshold limit, and that zones will be shut off to preserve the surface facilities. Opportunity was grabbed to optimize number of wells by completing both shallow and intermediate sections in a single selective completion to maximize the project value. However, this combination will lead to major challenges during operation due to the huge difference in reservoir pressure and permeability contrast in each perforated reservoir as the required overbalanced pressure of completion brine for shallow reservoir is much lesser than the requirement for the mildly overpressure intermediate reservoir. Thus, a potential risk of severe losses and well control is present at shallow reservoir. To mitigate this risk, loss circulation material was pre-spotted in the TCP (Tubing conveyed perforation) BHA prior to fire the gun to allow for self-curing process should losses take place. During the first development campaign, the completion tubing was running in hole in two stages. The lower completion was deployed via drill pipe and the perforated zones was secured with fluid loss device located between lower completion tubing and gravel pack packer. The upper completion tubing was then deployed and tied back to the lower completion packer. This approach was applied as mitigation to prevent fluid losses and to ensure the tubing can be safely deployed to the intended final depth. However, based on the actual performance and losses rate data during the first campaign, the completion design in second campaign was optimized and deployed in single stage. Since shallow and intermediate reservoir were combined in multiple production zones where five SSD (Sliding Side Door) were installed, the slickline option to set packer was waived due to the risk of setting tubing plug in deep wells. Pump out plug was considered as an option but then dropped due to high hydrostatic pressure. The packer setting pressure was too close to plug shear pressure. Therefore, a self-disappearing plug was utilized as it did not require any slickline intervention and can be ruptured by pressure cycle. With this option, risk of pre-mature rupture of plug was eliminated. The paper will discuss in detail each challenge mentioned above together with details calculation that was performed throughout evaluation and selection processes prior best solution being selected as these optimizations resulted in nearly three days saving of rig time, contributing to 2.6% of well cost reduction and the required number of wells were optimized to be three instead of four wells. Moreover, a safer production life of wells by selecting a suitable tubing material and eliminating the risk of mercury production above the above threshold limit.
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