First Multistage Hydraulic Fracturing in Russian Offshore: Integrated Approach to Completion and Stimulation of Apt Deposits of V.Filanovsky Field

M. Golenkin, D. Eliseev, A. Zemchikhin, A. Borisenko, Akhmat Sakhadinovich Atabiyev, E. Sorokin, Yevgeniy Orestovich Mikitin, Aidar Biktimirovich Khusainov, Andrey Valeryevich Liplyanin, Andrey Valeryevich Sidorov, Rustem Talgatovich Bashirov, Sergey Anatolyevich Goryachev
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Abstract

The paper describes the results of the first multistage hydraulic fracturing operations in Russia on the Caspian Sea shelf in the gas condensate and oil deposits of the Aptian formation of V. Filanovsky field. In addition to the small productive formation depth, long horizontal sections with a complex trajectory and high collapse gradients due to large zenith angles when passing the Albian and Aptian deposits of poorly consolidated sandstones are an additional challenge for choosing a multistage hydraulic fracturing assembly. The above features require the use of modern sand control screens with enhanced frac sleeves. A design was developed which includes frac sleeves and sand control screens that can withstand multiple cycles of hydraulic impact during hydraulic fracturing, as well as many opening/closing cycles. A seawater-based frac fluid system was applied. The frac fleet was located on a pontoon, the coiled tubing – on a platform. For the first time in Russia, a 2-5/8 inch coiled tubing with a complex-type friction reducing system was used to switch coupling/sleeves in conditions of very long horizontal sections, complex trajectories, and high friction coefficients. The minimum distances between the screen's sliding sleeves and frac sleeves did not prevent from performing manipulations in complex environment. For well cleaning, the frac assemblies of reverse rotary-pulse and rotary-directional types were used. At the first stage of the project, the development of an optimal method of well completion was successfully implemented. Due to the close interaction of the operating company, service company, and science & engineering team of the operator, for the first time in Russia the design of downhole equipment with the use of advanced technologies of sand control screens, frac sleeves was presented. This solution has proved its effectiveness – the downhole equipment has retained its operational properties after a long period of well operation and further in the process of hydraulic fracturing. At the second stage of the project, 32 MSHF operations were performed at four wells. To reduce nonproductive time and operational risks, a satellite communication complex was additionally deployed on the pontoon to join the engineering centers of Astrakhan, Moscow, and Houston. After finishing the well development, the design indicators for formation fluid rates were achieved, which proved the effectiveness of the stimulation of the field's target objects – this opens great prospects for further development of low-permeability reservoirs at offshore sites in the Caspian Sea. The successful project implementation and the achievement of the design values of oil flow rates has expanded the possibilities of commercial operation of the low-permeable Aptian formation, complicated by the presence of a gas cap and underlying water. A solution was presented for working in extended horizontal well sections with 2-5/8 inch coiled tubing together with a complex-type mechanical friction reducing system. The economic effect was achieved when solving tasks of manipulating mechanical screen couplings and frac port sleeves without the involvement of downhole tractors. The use of new solutions in the completion assembly made it possible to eliminate additional sand ingress problems.
俄罗斯海上首次多级水力压裂:V.Filanovsky油田Apt储层完井和增产的综合方法
本文介绍了俄罗斯在里海大陆架V. Filanovsky油田Aptian组凝析油和油田进行的第一次多级水力压裂作业的结果。除了生产地层深度小之外,在经过Albian和Aptian砂岩固结不良的矿床时,由于天顶角大,长水平段具有复杂的轨迹和高坍塌梯度,这是选择多级水力压裂组合的另一个挑战。上述特点需要使用带有增强型压裂滑套的现代防砂筛管。开发的设计包括压裂滑套和防砂筛管,可以承受水力压裂过程中的多次水力冲击,以及多次开启/关闭循环。应用了一种海水基压裂液体系。压裂车队位于平台上的一个浮桥上,即连续油管。在俄罗斯,首次使用2-5/8英寸的连续油管与复杂的减阻系统,在非常长的水平段、复杂的轨迹和高摩擦系数的条件下切换联轴器/滑套。筛管滑动滑套与压裂滑套之间的最小距离并不妨碍在复杂环境中进行操作。清洗井时,采用了反旋转脉冲式和旋转定向式压裂组合。在项目的第一阶段,成功地开发了一种最佳完井方法。由于作业公司、服务公司和作业者的科学与工程团队的密切互动,在俄罗斯首次提出了采用防砂筛管、压裂滑套等先进技术的井下设备设计。该方案已被证明是有效的,井下设备在长时间的井作业后,甚至在水力压裂过程中,仍能保持其作业性能。在项目的第二阶段,在4口井中进行了32次MSHF作业。为了减少非生产时间和操作风险,在浮筒上额外部署了卫星通信综合体,以连接阿斯特拉罕、莫斯科和休斯顿的工程中心。在完成井开发后,获得了地层流体速率的设计指标,证明了油田目标层增产的有效性,这为里海海上低渗透油藏的进一步开发开辟了广阔的前景。项目的成功实施和油流量设计值的实现,扩大了低渗透Aptian地层商业运营的可能性,由于气顶和底层水的存在而变得复杂。提出了一种采用2-5/8英寸连续油管配合复杂机械减阻系统在大水平井段作业的解决方案。在没有井下拖拉机的情况下,解决了操纵机械筛管联轴器和压裂口滑套的任务,取得了经济效益。在完井组合中使用新的解决方案可以消除额外的入砂问题。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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