解决阿曼差异枯竭致密气藏直井水力压裂面临的挑战

Khalfan Mubarak Al Bahri, J. Chaves, A. A. Al Hinai, Ahmed Hamed Abdullah Al Sulaimani, A. Nunez
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引用次数: 0

摘要

水力压裂一直是阿曼致密气开发的关键技术。这种致密气聚集是在直井的支撑下开发的,不同深度的裂缝覆盖了多达10个不同的碳氢化合物单元。致密单元固有的地质力学、岩石物理和岩性非均质性不仅影响裂缝导电性分布,还影响裂缝带的排液效率,这可以通过该单元内的流度变化来观察,一旦所有流度都混合在一起,流度较高的区域将主导气井总产量。预计高机动性单位的耗竭将影响和改变混合生产的贡献动态。然而,这只是油田开发过程中水力压裂策略中需要考虑的挑战的一个方面。本文将重点关注关键的操作挑战和基本的地层表征要求,以评估油田生命周期内的地应力动态变化;将地层压力点作为钻井计划的组成部分,并在井筒稳定性评估和小型压裂作业的支持下进行地应力测量。随着油田的开发,压力和应力分布的变化将如何影响射孔和压裂策略以及确保井完整性的压力操作包封层。本文将描述测井要求以及确定关键弹性特性所需的实验室特征,以评估压裂单个单元或组合的水力要求。本文将讨论压力约束的增加如何潜在地影响在特定气体单元上经历枯竭时的原位弹性特性,引起应力剖面的改变,从而影响裂缝扩展和最终的导电性分布。利用放射性示踪剂与生产测井相结合来评估围封和裂缝预测,为确定裂缝扩展行为、部署策略和最终导电性分布提供了重要工具。还将讨论包括桥塞磨铣、压裂后清井和举升等关键操作。最后,将介绍关键的观察结果,这些观察结果可以作为不同枯竭地层裂缝部署方法的一部分,从而在最大限度地提高投资的同时实现最佳的油田开发。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Addressing the Challenges of Hydraulic Fracturing Vertical Wells in Differential Depleted Tight Gas Accumulations in Oman
Hydraulic fracturing has been a key technology enabler for the development of tight gas formations in Oman. This tight gas accumulation has been developed with the supported of vertical wells, fractured at different depth covering up to 10 different hydrocarbons units. The intrinsic geomechanical, petrophysical and lithological heterogeneities of this tight units impact not only the fracture conductivity distribution but the drainage efficiency of the fractured zones, this is observed as mobility variations across this unit impact their contributions once all become commingle, with the areas of higher mobility dominating the total gas well production. It was anticipated that depletion of the higher mobility units will impact and change the contribution dynamics of the commingle production. However, this is only one dimension of the challenges to be considered as part of the hydraulic fracture strategy during the field development. This paper will be focus key operational challenges and the fundamental formation characterization requirements to assess in-situ stress dynamic variations during the life of the field; incorporating formation pressure points as integral part of the drilling program and in-situ stress measurements supported by wellbore stability evaluation and mini-fracture operations. It will be presented how variations on pressure and stress profiles, as the field developed, will impact the perforation and fracture strategies as well as pressure operating envelop to assure well integrity. It will be described the logging requirements as well as the lab characterization needed to determine key elastic properties to assess the hydraulic requirements for fracturing individual units or combination of them. It will be discussed how increase of pressure confinement potentially affects the in-situ elastic properties as depletion is experienced on specific gas units, inducing alterations on stress profiles that impact fracture propagation and final conductivity distribution. The use of radioactive tracers in combination with production logging were implemented to assess containment and fracture prediction, providing this an essential tool to determine fracture propagation behavior, deployment strategy and final conductivity distribution. Key operations covering plug milling, post fracture clean out and well lifting will be also discussed. Finally, it will presented key observation that can be implemented as part of methodologies used for fracture deployment on differential depletion formation, this leading to optimum field development while maximize investment.
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