ERD wells are commonly associated with major challenges for installation of casing and liner strings. These wells typically present high torque and drag parameters that jeopardize getting strings to total depth. In an attempt to optimize production, a major oil company in Angola decided to re-enter the study well in early 2016. A sidetrack was opened in the 9 5/8-in. casing, and drilling continued in the 8 (1/2)-in. hole and penetrated the target zone in the highest location. Then a 7-in. production liner was run. To reach the target zone, 5,583 ft of 8 (1/2)-in. hole was drilled and deviations varied from 45° to 87°. This trajectory was a challenge for subsequent running of 7-in. liner. Torque and drag (T&D) models showed liner rotation at total depth (TD) was not possible, and a surge model indicated likelihood of mud losses while running the liner. Liner hanger technologies became a very important phase of well construction, and service companies developed advanced liner hangers to overcome hostile well environments. In this case study, the short time available from the planning to execution phases and the current oil market conditions made it imperative that the right equipment, service, and technology were available in country. To achieve the ideal working parameters and get the liner to bottom, a thorough assessment needed to be performed to ensure risk mitigation. This paper presents summarizes steps considered during planning for the 7-in. liner run including a detailed engineering analysis that enabled the operator to make the best decisions based on the available resources. The paper will also discuss lessons learned and best practices captured during the job that will be used for subsequent liners in similar wells. The case study well was planned as a sidetrack from an existing well that had been shut in because of low performance. The main well had been drilled and completed as a single gravel pack in 2007. The objective of the sidetrack was to penetrate the reservoir organized complex in the structurally highest location to access reserves and optimize production. A constrained initial production was estimated at 6035 BFPD. An operations overview of the complete intervention is as follows: 1. Set a 8 (1/2)-in. whipstock in existing 9 5/8-in. casing at 8,400 ft and mill the window. 2. Drill an 8 (1/2)-in. hole section to 13,923 ft MD / 6,657 ft TVD. 3. Run and cement 7-in. liner. 4. Displace the hole with completion fluid. 5. Perform cement bond logs and hand the well over to completion.
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机译:ERD Wells通常与用于安装套管和衬垫弦的主要挑战有关。这些井通常呈现高扭矩和拖动参数,危害将字符串变为总深度。在试图优化生产中,安哥拉的主要石油公司决定在2016年初重新进入这项研究。在9 5/8英寸中开业。套管和钻井在8(1/2)-IN中继续。洞并穿过最高位置的目标区域。然后是一个7英寸。生产衬垫运行。到达目标区,5,583英尺8(1/2)-in。钻孔孔,偏差从45°到87°变化。这种轨迹是一个挑战,以便随后运行7-in。衬垫。扭矩和拖动(T&D)模型在总深度(TD)下显示衬垫旋转是不可能的,并且浪涌模型表示运行衬里时泥浆损失的可能性。衬里衣架技术成为一个非常重要的井建筑阶段,服务公司开发出先进的衬里衣架,以克服敌对的井环境。在这种情况下,从计划执行阶段获得的短时间和当前的石油市场条件使得恰当的设备,服务和技术势在必行。为了实现理想的工作参数并将衬垫置于底部,需要进行全面的评估,以确保风险缓解。本文提出总结7英寸计划期间考虑的步骤。衬垫运行包括详细的工程分析,使操作员能够根据可用资源来实现最佳决策。本文还将讨论在工作期间捕获的经验教训和最佳实践将用于类似井中的后续衬垫。案例研究良好的是由于性能低而被关闭的现有井的侧面。主要井在2007年被钻井并完成了单个碎片包。侧面的目的是在结构最高的位置渗透到储存器中,以获得储备和优化生产。受限制的初始生产估计在6035 BFPD。完整干预的操作概述如下:1。设置8(1/2)-in。现有9 5/8英寸的鞭子。套管在8,400英尺和铣削窗口。 2.钻8(1/2)-in。孔部分至13,923 FT MD / 6,657 FT TVD。 3.运行和水泥7-in。衬垫。 4.将孔置于完井流体。 5.执行水泥键的日志,然后妥善处理完成。
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