将高分辨率岩心相集成到特拉华盆地Wolfcamp和Third Bone Spring Sand的盆地级地层模型中的机器学习工作流程

IF 1.1 4区 地球科学 Q3 GEOCHEMISTRY & GEOPHYSICS
T. Larson, J. E. Sivil, Priyank Periwal, J. Melick
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引用次数: 0

摘要

泥岩沉积体系固有的非均质性和高度的空间变异性阻碍了以泥岩相为主的地下储层的表征。地下储层的性质,包括孔隙度和渗透率、流体饱和度、储层单元的地层厚度和烃源岩潜力,最终由沉积岩相的空间分布控制,这有助于改善地下表征工作流程。尽管基于岩心的数据提供了用于静态储层模型的岩石属性的直接测量,但捕获高分辨率基于岩心的岩石相并缩小这些观察结果以与低分辨率电缆测井相结合仍然是一个挑战。当试图捕捉泥岩系统中常见的薄层非均质性时,将岩心相与储层尺度模型相结合的努力尤其困难。在此,开发了一个工作流,并将其应用于可视化和集成多变量和空间复杂的基于岩心的数据集与电缆测井。基于地层特定岩心的化学相训练数据集是通过将岩心描述与高分辨率x射线荧光岩心扫描得出的化学相簇相结合而开发的。基于岩心的岩石属性数据(如x射线衍射矿物学、总孔隙度和总有机质含量)用于描述化学相,为将低分辨率岩石属性测量提高到高分辨率岩心化学相提供了一种手段。然后,将有监督的基于岩心的化学相训练数据集与神经网络多类分类机器学习工具一起,训练三重组合电缆测井(伽马射线、深部电阻率、体积密度和中子孔隙度),从电缆测井中预测岩石相,为将基于岩心的相分类应用于电缆测井研究提供了一种新的方法。在美国西德克萨斯州特拉华盆地的第三骨泉砂和Wolfcamp组单元中,描述了一个应用该工作流程的盆地规模案例研究。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A machine learning workflow to integrate high-resolution core-based facies into basin-scale stratigraphic models for the Wolfcamp and Third Bone Spring Sand, Delaware Basin
Characterization of subsurface reservoirs that are dominated by mudrock facies is hindered by the inherent heterogeneity and high degree of spatial variability typical of mudrock depositional systems. Subsurface reservoir properties that include porosity and permeability, fluid saturations, stratigraphic thicknesses of reservoir units, and source rock potential are ultimately controlled by the spatial distribution of sedimentary rock facies, which supports efforts to improve subsurface characterization workflows. Although core-based data provide direct measurements of rock attributes that are used to inform static reservoir models, capturing high-resolution core-based rock facies and downscaling these observations to tie to lower-resolution wireline logs remains a challenge. The effort to integrate core-based facies to reservoir-scale models is especially difficult when trying to capture thin-bedded heterogeneity that is common to mudrock systems. Herein a workflow is developed and applied to visualize and integrate multivariate and spatially complex core-based datasets with wireline logs. Formation-specific core-based chemofacies training datasets are developed by integrating core descriptions with chemofacies clusters developed from high-resolution X-ray fluorescence core scanning. Core-based rock attribute data (e.g., X-ray diffraction mineralogy, total porosity, and total organic matter content) are used to describe the chemofacies, providing a means to upscale low-resolution rock attribute measurements to high-resolution core-based chemofacies. Supervised core-based chemofacies training datasets are then used with neural network multi-class classification machine learning tools to train triple combo wireline logs (gamma ray, deep resistivity, bulk density, and neutron porosity) to predict rock facies from wireline logs, providing a new approach to apply core-based facies classifications to wireline log studies. A basin-scale case study that applies this work flow is described for the Third Bone Spring Sand and units of the Wolfcamp Formation in the Delaware Basin of West Texas, United States.
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来源期刊
CiteScore
2.50
自引率
8.30%
发文量
126
期刊介绍: ***Jointly published by the American Association of Petroleum Geologists (AAPG) and the Society of Exploration Geophysicists (SEG)*** Interpretation is a new, peer-reviewed journal for advancing the practice of subsurface interpretation.
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