The Early Determination Method of Reservoir Drive of Oil Deposits Based on Jamalbayli Indexes

SPE Journal Pub Date : 2024-07-01 DOI:10.2118/221480-pa
M. Jamalbayov, Betul Yildirim, Atilla Abdullazada
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Abstract

Historically, the concept of “reservoir drive” aimed to simplify the mathematical modeling in reservoir engineering. Within this framework, the energy of the reservoir, particularly its aquifer, was idealized, leading to classifications such as “partial waterdrive,” “full waterdrive,” “gas cap drive,” and so forth. However, in reality, all existing energy sources interact simultaneously within reservoirs. Accordingly, this study aims to develop a new concept for a more realistic description of reservoir drive mechanisms and evaluation of reservoir energy performance. Numerous computer simulations have revealed a strong correlation between the ratio of relative changes in pore volume to relative changes in reservoir pressure and the reservoir’s energy nature and activity level. Moreover, the noted ratio did not depend on production technology, pressure/volume/temperature properties of hydrocarbon systems, rheological properties of reservoir rocks, or other factors. Based on this correlation, specific parameters termed as Jamalbayli Indexes (JI) have been identified to quantitatively describe reservoir energetic performance. JI consist of two parameters. One of them describes the relative change in pore volume per unit of relative change in reservoir pressure, and the second is the relative change in pore volume per unit of relative change in formation porosity. Here, “relative change” means a change in a parameter relative to its original value. These parameters are dimensionless and can have values around or equal to unity. A new conceptual framework for describing reservoir drive mechanisms based on JI has been formulated. According to this framework, reservoir drive mechanism is determined by comparing the computed JI values with unity rather than relying on subjective assessments of the trend of some functional dependencies. For the first time, it has become possible to express the reservoir drive performance quantitatively and determine the level of energy activity of the reservoirs with the help of JI. Additionally, a technique has been developed to evaluate the numerical values of JI for specific oil (including volatile oil) deposits based on the production data at any stage of production. The proposed methodology was tested using data from the eighth horizon of the Russkiy Khutor field in Russia. The test results not only confirmed the reliability of the obtained model but also demonstrated the adequacy of the proposed concept as a whole. Summarizing the results of other works by the authors, the adequacy of the proposed concept for both oil, gas, and gas condensate deposits has been confirmed. The research findings are expected to contribute to updating the traditional principles used for the mathematical problem statements in fluid flow in porous formations.
基于贾迈勒拜利指数的油藏驱动力早期确定方法
历史上,"储层驱动 "的概念旨在简化储层工程的数学模型。在这一框架内,储层(尤其是含水层)的能量被理想化,从而产生了 "部分水驱"、"全水驱"、"气帽驱 "等分类。然而,在现实中,所有现有的能源都同时在水库中相互作用。因此,本研究旨在提出一个新概念,以更真实地描述储层驱动机制和评估储层能量性能。大量的计算机模拟显示,孔隙体积相对变化与储层压力相对变化的比率与储层的能量性质和活动水平之间存在着很强的相关性。此外,该比率并不取决于生产技术、碳氢化合物系统的压力/体积/温度特性、储层岩石的流变特性或其他因素。根据这种相关性,确定了称为贾迈勒拜利指数(JI)的特定参数,用于定量描述储层的能量性能。JI 由两个参数组成。其一是储层压力相对变化单位内孔隙体积的相对变化,其二是地层孔隙度相对变化单位内孔隙体积的相对变化。这里的 "相对变化 "是指参数相对于其原始值的变化。这些参数都是无量纲参数,其值可以接近或等于统一值。在联合执行的基础上,制定了描述储层驱动机制的新概念框架。根据这一框架,水库驱动机制是通过比较计算出的联合强度值与统一值来确定的,而不是依赖于对某些功能依赖性趋势的主观评估。在 JI 的帮助下,首次实现了定量表达水库驱动性能和确定水库能量活动水平。此外,我们还开发了一种技术,可根据任何生产阶段的生产数据,评估特定石油(包括挥发性石油)储藏的 JI 数值。使用俄罗斯 Russkiy Khutor 油田第八层的数据对所提出的方法进行了测试。测试结果不仅证实了所获模型的可靠性,还证明了所提出概念的整体适当性。综合作者的其他研究成果,已证实所提出的概念适用于石油、天然气和凝析气矿床。预计研究成果将有助于更新多孔地层流体流动数学问题陈述的传统原则。
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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