Rock type based-estimation of pore throat size distribution in carbonate reservoirs using integrated analysis of well logs and seismic attributes

IF 1.1 4区 地球科学 Q3 GEOLOGY Carbonates and Evaporites Pub Date : 2024-04-06 DOI:10.1007/s13146-024-00954-5
Sirous Hosseinzadeh, Amir Mollajan, Samira Akbarzadeh, Ali Kadkhodaie
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Abstract

Depositional setting characterization is one of the most important tasks in petroleum basin analysis. In this regard, artificial intelligence has emerged as a game-changer in the field of oil reservoir characterization, offering a myriad of benefits that significantly enhance the exploration and production processes within the oil and gas industry. Artificial Intelligence driven algorithms can efficiently process geological and geophysical data, well logs, and seismic information, allowing for a more comprehensive understanding of reservoir properties. To obtain more appropriate image of high reservoir quality zones, a case study was performed by integrating 3D seismic and well data related to on onshore oilfield, west of Iran. Supporting data were acquired from existing geochemical analyses of scanning electron microscope, thin-section investigation, and special core analysis laboratory measurements related to three wells of the studied oil field. The methodology developed in this study consists of three main phases, at the first step a complete thin section analysis is done to identify the main facies of the studied reservoir. Four mains microfacies and representative sedimentary environment were identified including: (a) Foraminifera bioclastic wackestone (Mid ramp-Distal), (b) Benthic foraminifera bioclast peloid wackestone to packstone (Mid ramp-Proximal), (c) Coated grains bioclast packstone to grainstone (Inner ramp-Shoal), (d) Bioclast Peloid wackestone (Inner ramp-Lagoon). To create a continuous pore throat size log, porosity and permeability logs were initially generated through petrophysical evaluation and artificial neural network analysis, achieving an accuracy of R2 = 0.95 for porosity and R2 = 0.84 for permeability. Subsequently, the pore throat size log was generated using the Winland equation, and the results were calibrated with pore throat sizes calculated from capillary pressure data analysis using the Washburn equation. Two different approaches including FZI and K-means clustering methods are also employed to recognize Hydraulic Flow Units. According to the Sum of Squared Errors (SSE) plot of the K-means algorithm, beyond three clusters, the reduction in SSE becomes marginal, suggesting that three clusters suit the dataset appropriately. In the next step, the sparse spike algorithm was used to generate a 3D acoustic impedance cube. Finally, post-stack seismic attributes, including the inverse of acoustic impedance, instantaneous frequency, a filter of 15/20–25/30, and amplitude-weighted phase, were selected to create a 3D pore throat size cube using a Probabilistic Neural Network, demonstrating a strong correlation of R2 = 91. The resulting pore throat size cube effectively illustrates that the Ilam-Upper and Ilam Main zones, which include HFU 3, exhibit high reservoir quality, with porosity, permeability, and mean pore throat size values of 16%, 20–67 mD, and 3–6 microns, respectively. In summary, the integration of acoustic impedance in oil reservoir characterization revolutionizes how we extract and manage hydrocarbon resources, driving efficiency, cost-effectiveness, and sustainability.

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基于岩石类型的碳酸盐岩储层孔喉尺寸分布估算(使用测井记录和地震属性综合分析法
沉积环境特征描述是石油盆地分析中最重要的任务之一。在这方面,人工智能已成为油藏特征描述领域的游戏规则改变者,它带来了无数好处,极大地促进了石油和天然气行业的勘探和生产过程。人工智能驱动的算法可以高效处理地质和地球物理数据、测井记录和地震信息,从而更全面地了解储层特性。为了获得更合适的高储层质量区图像,我们通过整合伊朗西部陆上油田的三维地震和油井数据进行了一项案例研究。辅助数据来自现有的扫描电子显微镜地球化学分析、薄片调查以及与所研究油田的三口油井相关的特殊岩心分析实验室测量。本研究开发的方法包括三个主要阶段:第一步是进行完整的薄片分析,以确定所研究储层的主要岩相。确定了四个主要微岩层和具有代表性的沉积环境,包括:(a) 有孔虫生物碎屑瓦基岩(斜坡中段-远端),(b) 底栖有孔虫生物碎屑颗粒瓦基岩至包裹岩(斜坡中段-近端),(c) 包裹颗粒生物碎屑包裹岩至颗粒岩(斜坡内段-浅滩),(d) 生物碎屑颗粒瓦基岩(斜坡内段-泻湖)。为了创建连续的孔喉尺寸记录,最初通过岩石物理评估和人工神经网络分析生成孔隙度和渗透率记录,孔隙度的精确度达到 R2 = 0.95,渗透率的精确度达到 R2 = 0.84。随后,使用温兰方程生成孔喉尺寸记录,并将结果与使用沃什伯恩方程通过毛细管压力数据分析计算出的孔喉尺寸进行校准。此外,还采用了两种不同的方法(包括 FZI 和 K-means 聚类方法)来识别水力流动单位。根据 K-means 算法的平方误差和(SSE)图,超过三个聚类后,SSE 的降低变得微不足道,这表明三个聚类适合数据集。下一步,使用稀疏尖峰算法生成三维声阻抗立方体。最后,选择叠后地震属性,包括声阻抗倒数、瞬时频率、15/20-25/30 滤波器和振幅加权相位,利用概率神经网络创建三维孔喉尺寸立方体,显示出 R2 = 91 的强相关性。由此产生的孔喉尺寸立方体有效地说明,包括 HFU 3 在内的伊拉姆-上区和伊拉姆主区显示出较高的储层质量,孔隙度、渗透率和平均孔喉尺寸值分别为 16%、20-67 mD 和 3-6 微米。总之,将声阻抗集成到油藏表征中,彻底改变了我们开采和管理碳氢化合物资源的方式,提高了效率、成本效益和可持续性。
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来源期刊
Carbonates and Evaporites
Carbonates and Evaporites 地学-地质学
CiteScore
2.80
自引率
14.30%
发文量
70
审稿时长
3 months
期刊介绍: Established in 1979, the international journal Carbonates and Evaporites provides a forum for the exchange of concepts, research and applications on all aspects of carbonate and evaporite geology. This includes the origin and stratigraphy of carbonate and evaporite rocks and issues unique to these rock types: weathering phenomena, notably karst; engineering and environmental issues; mining and minerals extraction; and caves and permeability. The journal publishes current information in the form of original peer-reviewed articles, invited papers, and reports from meetings, editorials, and book and software reviews. The target audience includes professional geologists, hydrogeologists, engineers, geochemists, and other researchers, libraries, and educational centers.
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