基于先进机器学习的碳酸盐岩储层岩相分类——以伊拉克南部油田为例

Mohammed A. Abbas, W. Al-Mudhafar
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引用次数: 4

摘要

从复杂碳酸盐岩非取心井的岩石物理测井资料中估算岩相是改善储层表征和油田开发的一项关键任务。因此,根据储层的流量和储层能力来识别储层的岩相是至关重要的。本文在伊拉克南部Majnoon大油田Mishrif碳酸盐岩储层的一口井中,采用了一种创新的方法,利用数据驱动的机器学习进行岩相分类。采用随机森林方法,利用取心井测井资料进行岩相分类,预测其在其他非取心井中的分布。此外,实现了三种先进的统计算法:Logistic Boosting回归、Bagging多元自适应回归样条和广义Boosting建模,并与随机森林方法进行了比较,以获得最真实的岩相预测。该数据集包括测量的离散岩相分布和整个储层段的井径测井曲线、伽马射线测井曲线、中子孔隙度测井曲线、体积密度测井曲线、声波测井曲线、深、浅电阻率测井曲线。在应用四种分类算法之前,对数据集进行随机子抽样交叉验证,分别产生用于建模和预测的训练子集和测试子集。在预测离散岩相分布后,采用混淆表(Confusion Table)和正确分类率指数(Correct Classification Rate Index, CCI)作为进一步的标准,对四种分类算法的有效性进行了分析和比较。研究结果表明,随机森林在岩相分类方面比其他方法更准确。通过训练子集的CCI达到100%,验证子集的CCI达到96.67%,使得观察到的离散岩相与预测之间的匹配非常好。通过将预测的每个离散岩相与核磁共振测井获得的孔隙度和渗透率的可用范围进行比较,进一步验证了所得相模型。研究发现,以粗砂岩为主的岩相与孔隙度和渗透率较高的岩石相对应。而泥质岩相则与孔隙度和渗透率较低的岩石相对应。此外,随后将这些高渗透率和低渗透率范围与从PLT测井数据中获得的产油率进行比较。结果表明,高、低渗透率范围分别与高、低油率测井曲线具有较好的相关性。总之,为了获得有意义的渗透率-孔隙度关系和捕捉真实的储层非均质性,对非取心层段和井的岩相进行高质量估计是一项至关重要的储层表征任务。机器学习技术的应用降低了成本,节省了时间,并减少了岩相分类和预测的不确定性。整个工作流程是通过开源统计计算语言R完成的。它可以很容易地应用于其他储层,以获得类似的改进的整体储层特征。
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Lithofacies Classification of Carbonate Reservoirs Using Advanced Machine Learning: A Case Study from a Southern Iraqi Oil Field
Estimating rock facies from petrophysical logs in non-cored wells in complex carbonates represents a crucial task for improving reservoir characterization and field development. Thus, it most essential to identify the lithofacies that discriminate the reservoir intervals based on their flow and storage capacity. In this paper, an innovative procedure is adopted for lithofacies classification using data-driven machine learning in a well from the Mishrif carbonate reservoir in the giant Majnoon oil field, Southern Iraq. The Random Forest method was adopted for lithofacies classification using well logging data in a cored well to predict their distribution in other non-cored wells. Furthermore, three advanced statistical algorithms: Logistic Boosting Regression, Bagging Multivariate Adaptive Regression Spline, and Generalized Boosting Modeling were implemented and compared to the Random Forest approach to attain the most realistic lithofacies prediction. The dataset includes the measured discrete lithofacies distribution and the original log curves of caliper, gamma ray, neutron porosity, bulk density, sonic, deep and shallow resistivity, all available over the entire reservoir interval. Prior to applying the four classification algorithms, a random subsampling cross-validation was conducted on the dataset to produce training and testing subsets for modeling and prediction, respectively. After predicting the discrete lithofacies distribution, the Confusion Table and the Correct Classification Rate Index (CCI) were employed as further criteria to analyze and compare the effectiveness of the four classification algorithms. The results of this study revealed that Random Forest was more accurate in lithofacies classification than other techniques. It led to excellent matching between the observed and predicted discrete lithofacies through attaining 100% of CCI based on the training subset and 96.67 % of the CCI for the validating subset. Further validation of the resulting facies model was conducted by comparing each of the predicted discrete lithofacies with the available ranges of porosity and permeability obtained from the NMR log. We observed that rudist-dominated lithofacies correlates to rock with higher porosity and permeability. In contrast, the argillaceous lithofacies correlates to rocks with lower porosity and permeability. Additionally, these high-and low-ranges of permeability were later compared with the oil rate obtained from the PLT log data. It was identified that the high-and low-ranges of permeability correlate well to the high- and low-oil rate logs, respectively. In conclusion, the high quality estimation of lithofacies in non-cored intervals and wells is a crucial reservoir characterization task in order to obtain meaningful permeability-porosity relationships and capture realistic reservoir heterogeneity. The application of machine learning techniques drives down costs, provides for time-savings, and allows for uncertainty mitigation in lithofacies classification and prediction. The entire workflow was done through R, an open-source statistical computing language. It can easily be applied to other reservoirs to attain for them a similar improved overall reservoir characterization.
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