具有突水风险的油田开发的基本方面——是时候改变模式了

R. Nepop, Nikolay Smirnov, R. Molodtsov, V. Reyes Ahumada, M. Nizametdinova, J.J. Polushina, N. Kudlaeva, T.Y Dolgushin, A. Maltsev, Nikolay Khazov
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引用次数: 0

摘要

储层构造的地质特征对西西伯利亚地区油气田的开发具有重要意义。一个生产地层通常被认为是一个完整的系统,包括两个相互关联的组成部分:岩石和流体。在这一体系中,水的出现通常伴随着负面后果——地质基底弹性强度的降低和储层岩石稳定性的丧失。从井的建设和/或操作的角度来看,水的出现有多重要?寻找这个问题的答案已经成为本文提出的多学科研究的主要目标。在这些研究的框架内,对存在或穿透不同储层流体的裸眼井的实时稳定性进行了评估。计算基于高分辨率四维建模,考虑了不同生产场景规定的主要动力和地质力学效应。“岩石-流体”系统中相互关系的概念是基于特殊岩心研究的结果。这些实验的主要思想是重现储层的饱和条件,最初与过渡带有关,并以不同类型流体(地层水/油)的存在为特征。对重复样品进行了测试,这些样品具有非常相似的岩石物理性质,并且饱和了各种模型的地层流体。研究项目包括标准地质力学试验和厚壁圆筒试验,以及不同化学成分、盐度、温度和不同饱和方法影响的卤水试验。所得结果证实了地层流体对岩石弹性强度特性的实质性影响。同时,饱和流体的类型和饱和技术也起着重要的作用。分析了几种岩心材料饱和技术。它为计算流体和岩石不相容条件下的井筒稳定性、模拟水突破和出砂以及计算时间效应提供了关键知识。进一步的建模可以预测不同生产情景下裸眼稳定性的变化。最后,实验证明,即使在严重含水率(高达50%)的情况下,也可以保持井筒张开并继续作业。所获得的结果对于在开发后期评价油田的性能至关重要,特别是当存在水进入储层的风险时。目前业内的主要观点是,地层水的出现(突破)会导致岩石强度降低、出砂,最终导致井筒破坏。本研究的结果改变了这一范式。综合地质力学建模和岩心研究应用不同的饱和度技术,可以分析水渗透到储层的各种机制,这并不一定与随后的出砂和井筒破坏有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Fundamental Aspects of Oilfield Development with Water Breakthrough Risks - Time for a Paradigm Change
The geological features of the reservoir structure are of great importance in the development of oil and gas fields in the West Siberian. A productive formation is usually considered as an integral system that includes two interrelated components: rocks and fluid. In this system, the appearance of water is usually associated with negative consequences - a decrease in the elastic-strength properties of geological substrate and the loss of reservoir rocks stability. How critical is the emergence of water from a well construction and / or operation point of view? The search for an answer to this question has become the main goal of the multidisciplinary investigations presented in this paper. In the framework of these studies, an assessment of the in-time stability of an open borehole in case of presence or penetrating different reservoir fluids was carried out. The calculations were based on the high-resolution 4D modeling, which took into consideration the main dynamic and geomechanical effects stipulated by different production scenarios. The concepts of the interrelations in the "rock - fluid" system were based on the results of special core studies. The main idea of these experiments was to reproduce the saturation conditions of reservoirs, initially related to transition zones and characterized by the presence of different types of fluids (formation water / oil). Testing was carried out on duplicate samples, which were characterized by very similar petrophysical properties, and were saturated with various models of formation fluid. The research program included both standard geomechanical tests and experiments on a thick-walled cylinder, as well as experiments with brine of different chemical composition, salinity, temperature and affected by different methods of saturation. Obtained results confirmed the substantial influence of the formation fluid on the elastic-strength properties of the rocks. At the same time, a fundamental role is played not only by the type of saturating fluid, but also by the saturation technique. Several such techniques of core material saturation were analyzed. It provides critical knowledge for calculating the stability of the wellbore in conditions of incompatibility of fluids and rocks, modeling water breakthroughs and sand production, and also for calculating temporal effects. Further modeling made it possible to predict the change in open hole stability under different production scenarios. Finally, it was demonstrated that even with a significant water cut (up to 50%), it is possible to keep the wellbore open and to continue the well operation. The results obtained become critical for evaluating the performance of the field at a later stage of development, especially when there are risks of water breakthrough into the reservoir. The main paradigm in which the industry is currently operating is the idea that the appearance (breakthrough) of formation water leads to a decrease in the strength of the rocks, sand production and, finally, to the destruction of the wellbore. The results of presented study change this paradigm. Integrated geomechanical modeling and core studies applying different saturation techniques make it possible to analyze various mechanisms of water penetration into the reservoir, which is not necessarily associated with both subsequent sand production and wellbore destruction.
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