Do We Really Perforate Per the Design? Key Elements of Safer and High-Productivity Well Perforating

Hanaey Ibrahim, Ozgur Karacali, Y. Shumakov, Sulaiman Al Hinaai, Wafa Shizawi
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Abstract

Numerous perforation jobs are performed daily around the globe on a routine basis to establish wellbore to reservoir communication. However, in some cases, these perforating operations can result in poor well productivity or severe health, safety, security, and environment (HSSE) incidents. In this paper, the key elements of proper perforating operations, from data gathering to design and safest possible execution, are summarized to create practical guidelines for operators. Oil and gas wells are drilled, cased, cemented, and perforated as a result of diligently planned multidisciplinary engineering work. The engineers have traditionally designed perforations to have cleaner, larger, and deeper tunnels into reservoir rock to enhance the communication quality between the wellbore and reservoir. Research has proved that wellbore dynamics have significant control on the success of perforating activities during this fast-paced and short-lived event. Therefore, recently the trend has evolved from static underbalanced perforating to dynamic underbalanced perforating via advanced downhole gun system designs and downhole tools. Conventionally, operators have focused on debris and damaged rock removal from the perforation tunnels by applying static underbalanced perforating. However, static underbalance alone does not guarantee the optimal perforation tunnel structure. Research has shown that dynamic underbalance can significantly enhance tunnel cleanup and well productivity. Today, numerical perforating dynamics software is available to simulate wellbore dynamics for a given perforating design with various downhole tools. Perforating gun detonation pressures and the resulting shock waves can damage downhole tools and hinder wellbore integrity if not mitigated properly. In Oman, carefully designed and executed perforating operations have improved well productivity and operational safety for many years. Each perforating job is assiduously planned and executed. Specially designed software packages are used to simulate the wellbore conditions and downhole equipment response to identify and mitigate potential problems and to improve the efficiency of perforating tunnels cleanup prior to each perforating job. The application of this methodology has resulted in performing numerous highly successful perforating jobs in Oman. The results of these perforating jobs are presented here as case studies. The static and dynamic wellbore conditions as simulated and observed during the operations with a fast downhole gauge are compared and discussed in detail. Lessons learned and guidelines are presented in an easy-to-follow way to help operators achieve successful results. The methodologies and best practices outlined in this paper enable improved perforation designs by using available software in challenging environments where conventional approaches can be inadequate. The methodology is described systematically in detail so that the procedure and learnings from Oman's hydrocarbon producing wells and reservoirs can be adapted to other operations around the globe.
我们真的要按照设计打孔吗?安全、高产井射孔的关键要素
在全球范围内,每天都会进行大量射孔作业,以建立井筒与油藏之间的连通。然而,在某些情况下,这些射孔作业可能会导致油井产能下降或严重的健康、安全、安保和环境(HSSE)事故。本文总结了正确射孔作业的关键要素,从数据收集到设计和最安全的执行,为作业者提供实用指南。油气井的钻井、套管井、固井和射孔都是精心规划的多学科工程工作的结果。传统上,工程师们设计的射孔孔要更清洁、更大、更深,以提高井筒与储层之间的连通质量。研究证明,在这种快节奏、短时间的射孔活动中,井筒动态对射孔活动的成功与否具有重要的控制作用。因此,通过先进的井下射孔枪系统设计和井下工具,目前的趋势已经从静态欠平衡射孔发展到动态欠平衡射孔。传统上,作业者主要通过静态欠平衡射孔来清除射孔隧道中的碎屑和受损岩石。然而,仅靠静欠平衡并不能保证最佳射孔隧道结构。研究表明,动态欠平衡可以显著提高隧道清洁度和油井产能。如今,数值射孔动力学软件可以使用各种井下工具模拟给定射孔设计的井筒动力学。射孔枪的爆轰压力和由此产生的冲击波如果不能适当降低,可能会损坏井下工具,影响井筒完整性。在阿曼,精心设计和实施的射孔作业多年来提高了油井的产能和作业安全性。每次射孔作业都经过精心规划和执行。专门设计的软件包用于模拟井筒条件和井下设备响应,以识别和减轻潜在问题,并提高每次射孔作业前的射孔通道清理效率。该方法的应用已经在阿曼进行了许多非常成功的射孔作业。本文将这些射孔作业的结果作为案例进行介绍。利用快速井下测量仪模拟和观测了作业过程中的静态和动态井筒状况,并对其进行了详细的比较和讨论。经验教训和指导方针以易于遵循的方式呈现,帮助作业者取得成功的结果。本文概述的方法和最佳实践可以通过在传统方法可能无法胜任的具有挑战性的环境中使用可用的软件来改进射孔设计。系统详细地描述了该方法,以便将阿曼产油井和油藏的流程和经验应用于全球其他作业。
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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