传统设计的高产井作业装置:管道和仪表的挑战

J. L. Veiga, Antonio Jose Renno Chaves, Breno De Souza e Silva, Ivan Noville Rocha Correa Lima, Ilvan Porto Jr Pereira, Gilberto Jr Teixeira, Aldir Pimentel da Costa
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引用次数: 0

摘要

在Santos盆地最近的盐下开发的勘探设计阶段,发现了一些井的巨大生产潜力,对其在生产阶段的表现产生了很大的期望,超过了3万桶/天的平均产量。因此,考虑到从油井到FPSO的产量为45000桶/天,直径受到了限制。由于第一次石油生产,预期不仅成为现实,而且在很大程度上被取代,确认了每口井高达65,000桶/天的极高生产潜力,其中一些井在世界深水和超深水区产量最高的井中名列前茅。尽管这口井的潜力非常大,但由于考虑到每口井45,000桶/天的设计限制,无法实现充分生产,这超出了已经很高的预期。在这种情况下,为了使这些井的实际生产潜力可行,需要付出巨大的努力。为了使设计适应新的动态流动条件,我们动员了一个多学科的技术评估团队,涉及多个学科,如:海底设备、井、立管、过程、管道、仪表和自动化,以及操作安全,这是一个不容置疑的价值。在这些不同学科之间进行技术讨论之后,提出了可能在这种新的具有挑战性的条件下安全操作的备选方案。该措施已经实施,目前这些井已经在高水平生产。在拥有这些高产井的FPSO上,由于单个产量的增加,其潜力超过了设计能力的45%,从而显著提高了资产的盈利能力,为公司的现金流收入做出了贡献。本文介绍了处理高流速问题的管道和仪表研究。为了克服振动和腐蚀方面的挑战,采用了一种不同寻常的设计方法,因此进行了一些现场测试来验证该解决方案的有效性。这种替代方法可以提高每口井管道分支的产量。
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High Production Well Operating Plant in a Traditional Design: Piping & Instrumentation Challenges
During the exploration design phase of recent pre-salt development in Santos Basin, it was identified great potential for the production of some wells, generating great expectation by how it would perform in the production phase, above the average of 30,000 bpd. The Subsea and Topside design were developed based on this expectation and therefore, diameters were limited considering the premises of 45,000 bpd production from the well to the FPSO. As a result of first oil production the expectation not only became a reality but also was largely supersede, confirming a very high production potential of up to 65,000 bpd per well, some of which are at the world top list of highest production wells for deep and ultra-deep waters. Despite the outstanding high potential of the well, full production was then, not able to be achieved due to limitations considered in the design's premises of 45,000 bpd per well, what overcome the already great expectation. In this scenario, there was intense effort to make the real production potential of the wells viable. To fit the design to the new dynamic flow conditions, a multidisciplinary technical assessment team was mobilized involving several disciplines such as: Subsea Equipment, Wells, Risers, Process, Piping, Instrumentation and Automation, in addition to Operational Safety, a non-negotiable value. After technical discussions between those different disciplines, alternative proposals were raised that could make possible a safe operation under this new challenging condition. The defined actions were implemented and currently the wells already operate on high levels of production. On the FPSO with those high production wells, due to this individual increase in the production, whose potentials exceed by 45% the design capacity, generating a significant increase in the profitability of the asset, contributing to revenues anticipation in the company's cash flow. This article presents the piping and instrumentation study to deal with a high flow velocity issue. The methodology adopted to overcome the challenges in vibration and erosion considered an unusual design approach, leading to some field test to check the effectiveness of the solution. This alternative approach allowed this increment in production rate per well piping branch.
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