碳酸盐岩储层高分辨率研究的百万单元动态模型,第1部分

Faisal Al Jenaibi, M. Giddins, Adelis Valero, Samad Ali, Y. Saeed, A. Amtereg, A. Bajwa
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引用次数: 1

摘要

模拟高分辨率的百万单元模型带来了许多好处,使油藏工程师能够使用最佳网格尺寸来准确表示油藏中的水和气的运动,这对于先进的油田管理、提高石油采收率或复杂的井设计研究至关重要。为了更好地描述一个巨大的非均质碳酸盐岩储层,提高油田开发计划的质量,研究人员使用了新的高分辨率静态和动态模型来研究阿布扎比最大的油田之一。使用独特的含水饱和度建模方法构建了超过5000万个网格单元的详细静态模型,而没有升级到动态模拟,使用相对渗透率和毛细管压力的滞后。该油藏已有50多年的历史,拥有数百口直井和水平井。来自测井、岩心和其他测量的大量数据用于填充静态模型,定义动态岩石类型,并匹配测井含水饱和度和水毛管压力剖面。引入了润湿性随深度变化的概念,从顶部的油湿系统到靠近薄过渡区的水湿系统。在测试了输入数据的一致性和稳定性后,将地质分辨率网格用于储层模拟研究。在平衡后的50年里,在没有井的情况下进行了稳定性测试,结果显示没有可移动的流体。验证了储层静态性质、岩石类型、含水饱和度、相对渗透率和流体模型的一致性。为了实现在一天内完成每次模拟作业的目标,研究人员开发了850多口井的历史匹配案例,使用了相同的精细网格。在历史匹配之后,建立了一个成分模拟模型,以研究网格分辨率对未来产量预测的影响。这是该公司建立的最大的动态模型,并展示了严格关注静态数据质量的好处,同时使用现代仿真工作流程,以避免因升级而损害详细模型。本文中提出的方法将被采纳为未来类似项目的最佳实践。
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Multimillion Cell Dynamic Model for High Resolution Studies of a Carbonate Reservoir, Part-1
Simulating a high-resolution multimillion cell model brings many benefits, by enabling reservoir engineers to use the best grid size for accurate representation of water and gas movement in the reservoir, essential for advanced field management, Enhanced Oil Recovery or complex well design studies. To improve the characterization of a giant heterogeneous carbonate reservoir and enhance the quality of field development plans, new high-resolution static and dynamic models have been used to study one of the largest oil fields in Abu Dhabi. A detailed static model of over 50 million grid cells was constructed, using a unique water saturation modeling approach, without upscaling to a dynamic simulation, using hysteresis for both relative permeability and capillary pressure. The reservoir has over 50 years of history, with hundreds of vertical and horizontal wells. Large volumes of data from well logs, cores and other measurements were used to populate the static model, define dynamic rock types and match well log water saturation and water capillary pressure profiles. The concept of wettability change with depth was introduced, with an oil-wet system at the crest, graduating to a water-wet system near the thin transition zone. A geological resolution grid was used for reservoir simulation studies, after testing input data consistency and stable behavior. A stability test was performed by running the simulation with no wells for 50 years after equilibration and showed no movable fluids. This verified the consistency of the reservoir static properties, rock types, water saturation, relative permeability and fluid model. A history matched case was developed with over 850 wells using the same fine grid, to meet the objective of completing each simulation run within one day. After history matching, a compositional simulation model was built, to investigate the impact of grid resolution on future production forecasts. This is the largest dynamic model built by the company and demonstrates the benefits of rigorous attention to the quality of the static data, while using modern simulation workflows to avoid compromising the detailed model by upscaling. The methodologies presented in this paper will be adopted as best practices for future similar projects.
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