基于地质与地球物理信息分析的机器学习方法在Kharyaginsky油田泥盆系碳酸盐岩储层远景含油饱和度预测中的应用

S. Gusev, E. Kolbikova, O. Malinovskaya, A. Garaev, Robert Kamilevich Valiev
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引用次数: 0

摘要

Kharyaginskoye油田位于涅涅茨自治区境内,属于Timan-Pechora盆地油气省。主要开发对象为泥盆纪碳酸盐岩储层。研究对象的生产带主要局限于孔隙空间结构复杂的薄层低孔储层。由于储层横向非均质性强,且边缘隔离带存在不同程度的油水接触面(OWC),因此需要更准确地评估油饱和有效厚度。通过使用机器学习方法对井眼和地震研究进行联合分析,可以提高解释的可靠性。在基于测井和岩心数据的相模型配置阶段,采用了基于多分辨率图的聚类MRGC,实现了地质和地球物理信息的有效整合。基于k-最近邻算法(k-NN)的多维点模式识别方法,结合多种判据,解决了测井响应与岩性之间关系的非线性问题。采用神经网络DNNA民主关联算法在井间空间传播电相。该方法通过控制过程,优化了地震数据求和前和求和后以及井数据的使用,从而提供了经过校准和缩放的相分布。最可能的相分布可以直接用作储层建模的属性或作为建模的约束。众所周知,某种波型与岩石的岩性组成之间没有直接联系,因此,对反射特征变化的分析是结合地球物理资料(如测井)进行的。此外,还涉及到有关工作区域的先验地质信息。有效应用相分析的一个重要条件是具有代表性的岩心材料的存在和高质量井信息的可用性。在工作的第一阶段,根据岩心的宏观描述,以R. H. Dunham的灰岩分类为基础,对碳酸盐岩矿床进行了岩石分型。然后,利用多维统计识别算法MRGC,得到所选岩性与测井响应之间的关系。作为调整的结果,获得了一个簇模型,使我们能够区分以过滤和电容电位增加为特征的电相。第二阶段,考虑饱和性质,利用得到的电相对地震属性立方体进行训练,计算岩相立方体和各岩相存在的概率。分布的关键是利用在不同相带的井中获得的电相。因此,通过机器学习方法对所有可用的钻孔和地震信息进行联合分析,可以在地质和地球物理信息分析的基础上预测考虑饱和类型的岩相。通过对低渗透碳酸盐岩储层性质的分析,证明了该技术的有效性,在低渗透碳酸盐岩储层中,经典属性和反演在描述非均质饱和度模型时存在局限性。使用神经网络方法可以配置复杂的非线性依赖关系,这是经典方法无法实现的。在现场地球物理和地震解释领域,利用机器学习算法使用少量的多尺度地质和地球物理信息,可以提高解释的可靠性,并明确研究区域内储层性质改善的远景区域的位置,并在后续的井位过程中最大限度地降低地质风险。
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Forecast of Prospective Oil Saturation Zones in the Devonian Carbonate Deposits of the Kharyaginsky Field Based on Geological and Geophysical Information Analysis by Using Machine Learning Methods
The Kharyaginskoye oil field is located on the territory of the Nenets Autonomous District and belongs to the Timan-Pechora Basin oil and gas province. The main object of development is a Devonian age carbonate reservoir. The productive zones of the studied object are mainly confined to thin bed low-porosity reservoirs with a complex structure of void space. The high heterogeneity of deposits laterally and the presence of different levels of oil-water contact (OWC) in the marginal isolated zones necessitate a more accurate assessment of the oil-saturated effective thicknesses. The increase in the reliability of the interpretation was achieved by the joint analysis of borehole and seismic studies using Machine Learning methods. At the stage of configuring the facies model based on well logs and core data, a Multi-Resolution Graph-based Clustering MRGC was used, which provides effective integration of geological and geophysical information. The multi-dimensional dot-pattern recognition method based on k-Nearest neighbors algorithm (k-NN), and by combining various criteria, it allows solving the problem of non-linearity of the relationships between logging responses and the corresponding lithology. The algorithm of the democratic association of neural networks DNNA was used to propagate electrofacies in the inter-well space. The method optimizes the use of seismic data before summation and after summation together with well data through a controlled process that provides a calibrated and scaled distribution of facies. The most probable facies distribution can be used directly as a property in reservoir modeling or as a constraint for modeling. It is known that there is no direct connection between a certain type of wave pattern and the lithological composition of rocks, therefore, the analysis of changing reflection characteristics is performed in conjunction with geophysical data, such as well logging. In addition, a priori geological information about the work area is involved. An important condition for the effective application of facies analysis is the presence of representative core material and the availability of high-quality well information. At the first stage of the work, the lithotyping of carbonate deposits was performed according to the macro description of the core, based on the classification of limestones according to R. H. Dunham. Then, using the multidimensional statistical recognition algorithm MRGC, the relationships between the selected lithotypes and logging responses were obtained. As a result of the tuning, a cluster model was obtained that allows us to distinguish electrofacies characterized by an increased filtration and capacitance potential. At the second stage, the obtained electrofacies, considering the nature of saturation, were used to train cubes of seismic attributes and calculate the cubes of lithofacies and the probability of the existence of each lithofacies. The key point in the distribution was the use of electrofacies obtained in wells belonging to different facies zones. Thus, the joint analysis of all available borehole and seismic information by machine learning methods made it possible to make a forecast lithofacies considering the type of saturation based on geological and geophysical information analysis. The effectiveness of the presented technologies was demonstrated by analyzing the properties of low-permeable carbonate reservoirs, where classical attributes and inversion demonstrate limitations in describing a heterogeneous saturation model. The use of neural network approaches allows to configure complex nonlinear dependencies that are not available to classical methods. The use of a small volume of multi-scale geological and geophysical information using Machine Learning algorithms in the field of field-geophysical and seismic interpretation makes it possible to increase the reliability of interpretation and clarify the location of prospective zones with improved reservoir properties on the studied area, as well as to minimize geological risks during subsequent well placement.
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