压裂液工程技术的改进唤醒了北海巨头

Asif Hoq, Yann Caline, Erik Jakobsen, N. Wood, R. Stolpman, Aurelien Thirion, W. Giffin
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引用次数: 1

摘要

由AkerBP运营的Valhall油田一直是北海的主要枢纽,投产已有38年,最近的石油产量超过了10亿桶。为了经济生产,该油田需要进行增产改造。机械强度较强的地层采用酸刺激,而强度较弱的地层则需要设计出较大的筛顶支撑剂裂缝。自上世纪90年代以来,Valhall的裂缝部署方法一直保持相对不变,目前被称为“常规”。这些步骤包括放置支撑剂压裂,使用连续油管清理井眼,打开滑套或射孔,然后将线圈拉出井中泵入支撑剂压裂。在过去的几年里,AkerBP和他们的服务合作伙伴一直致力于为海上基础设施提供一种适合的环空连续油管压裂实践,这在业内是第一次,这已经成为运营商的战略重点,因为它大大缩短了执行时间并加快了生产。与所有技术试验一样,在Valhall上实施这一实践必须通过各种形式的挑战开始学习曲线。在调查环空压裂初期过早筛出的原因和频率的同时,该团队决定挑战常规的流体测试和质量控制标准。针对高剪切测试条件、温度建模和混合顺序进行了精心设计的调整,这些调整不仅确定了意外筛出的根本原因,而且有助于制定当前设计坚固流体的蓝图。由于使用了重新定义的配方,调整了测试程序,并对增产容器进行了更改,因此在执行过程中没有发生任何流体导致的筛出情况。配方中所需的添加剂种类减少,降低了处理成本,降低了凝胶载荷,减少了裂缝的损害,从而有助于提高油井的寿命。本文描述了研究结果,以及为适应高剪切和动态井筒温度条件而对流体配方和质量控制程序做出的改变。本文讨论了“现实”测试模型背后的基本原理,并证明了在将其投入大规模资本密集型作业之前,在实验室中投入时间彻底了解流体行为可以创造重大价值。研究表明,创新或挑战预先设想的做法总是有价值的,从这次调查中获得的经验教训大大改善了Valhall环空压裂的记录,重新定义了北海的流体工程,并将为未来在世界各地其他海上资产上的环空压裂部署提供指导。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Enhancements in Fracturing Fluid Engineering Reawakens a North Sea Giant
The Valhall field, operated by AkerBP, has been a major hub in the North Sea, on stream for thirty-eight years and recently passed one billion barrels of oil produced. The field requires stimulation for economical production. Mechanically strong formations are acid stimulated, while weaker formations require large tip-screenout design proppant fractures. Fracture deployment methods on Valhall have remained relatively unchanged since the nineties and are currently referred to as "conventional". Those consist in a sequence of placing a proppant frac, cleaning out the well with coiled tubing, opening a sleeve or shooting perforations, then coil pulling out of hole pumping the proppant frac. For the past few years, AkerBP and their service partners have worked on qualifying an adapted version of the annular coiled tubing fracturing practice for the offshore infrastructure - a first for the industry, which has been a strategic priority for the operator as it significantly reduces execution time and accelerates production. As with all technology trials, the implementation of this practice on Valhall had to begin on a learning curve through various forms of challenges. Whilst investigating the cause and frequency of premature screenouts during the initial implementation of annular fracturing, the team decided to challenge the conventional standards for fluid testing and quality control. Carefully engineered adjustments were made with regards to high shear testing conditions, temperature modelling, and mixing sequences, these did not only identify the root cause for the unexpected screenouts, but also helped create the current blueprint for engineering a robust fluid. Since the deployment of the redefined recipe, adjusted testing procedures and changes made to the stimulation vessel, there have not been any cases of fluid induced screenouts during the executions. The fewer types of additives now required for the recipe have lowered the cost of treatments and the lower gel loading leads to reduced damage in the fractures, thereby contributing to enhanced production over the lifetime of the wells. This paper describes the investigation, findings and the resulting changes made to the fluid formulation and quality control procedures to accommodate for high shear and dynamic wellbore temperature conditions. It discusses the rationale behind the "reality" testing model and, proves that significant value is created from investing time in thoroughly understanding fluid behaviour in the lab, prior to pumping it on large-scale capital-intensive operations. The study demonstrated that there is always value in innovating or challenging pre-conceived practices, and the learnings from this investigation significantly improved the track record for annular fracturing on Valhall, redefined fluid engineering for the North Sea and will inform future annular fracturing deployments on other offshore assets around the world.
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