综合地质数据、三维叠后地震反演、沉积建模和地质统计建模,为近场勘探更好地预测储层性质分布:利比亚苏尔特盆地东部的案例研究

IF 1.4 4区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
Geological Journal Pub Date : 2023-09-07 DOI:10.1002/gj.4870
Abdulhadi Elsounousi Khalifa, Zairi Moncef, Ahmed E. Radwan
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引用次数: 0

摘要

近场勘探中的油气潜力去风险是油气勘探中最重要的程序之一,需要整合各种数据才能更准确地预测勘探区的储层特征。在这项工作中,利用利比亚生产油田的油井和3D地震数据来证明这项技术在改善和描述古新世上萨比尔组碳酸盐岩地质体的油气潜力方面的作用,新的地震数据揭示了这一点。本研究整合了不同类型的数据,包括三维地震、地震声阻抗、沉积史和地质统计分析,以预测相、储层孔隙度和渗透率分布,然后将其可视化为三维储层模型。三维地震数据分析揭示了从未被任何井穿透的明显地震异常地质体(GB)的存在。GB附近井的沉积学分析表明,深水沉积环境为浊流岩,周围以深水泥浆为主。根据沉积相和地震地层学,将研究区上古新世层段细分为八个带,用于建立储层模型框架。根据孔渗关系,碳酸盐相可分为五个E相,即软质高泥质灰岩、硬质泥质灰石、多孔灰岩(页岩体积30%)、中质灰岩(孔隙度10-20%)和 >页岩体积的30%)和致密石灰岩(页岩体积的30%)。岩石物理和反演可行性分析表明,声阻抗(AI)可以用来预测孔隙度,但不能用来预测岩性或流体含量。贝叶斯分类在利用总沉积图(GDE)、井和地震数据的集成预测和建模研究区域内的储层相分布方面显示出良好的结果。GB的储层质量是通过使用叠后地震反演预测的,该反演表明孔隙度区间较高(25%-30%)。此外,将统计分析与井和地震数据相结合,用于预测GB渗透率。预测渗透率相当高(40-60 mD)。最终的E相显示出与输入井数据的良好匹配,以及与用于具有更高垂直分辨率的结果质量控制(QC)的盲井的良好匹配。所开发的模型可作为对所研究盆地中所研究的GB油气潜力进行风险评估的指南,也可应用于世界其他类似地质条件,以勘探未开发的储层并降低其油气潜力的风险。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Integrated geological data, 3D post-stack seismic inversion, depositional modelling and geostatistical modelling towards a better prediction of reservoir property distribution for near-field exploration: A case study from the eastern Sirt Basin, Libya

Integrated geological data, 3D post-stack seismic inversion, depositional modelling and geostatistical modelling towards a better prediction of reservoir property distribution for near-field exploration: A case study from the eastern Sirt Basin, Libya

De-risking the hydrocarbon potential in near-field exploration is one of the most important procedures in the exploration of hydrocarbons, and it requires the integration of various data to predict the reservoir characteristics of the prospect area more accurately. In this work, wells and 3D seismic data from the Libyan producing oil fields were utilized to demonstrate how well this technique worked to improve and describe the hydrocarbon potential of the carbonate geobody that corresponds to the Palaeocene Upper Sabil Formation, which was revealed by new seismic data. This study integrates different types of data, including 3D seismic, seismic acoustic impedance, depositional history and geostatistical analysis, to predict the facies, reservoir porosity and permeability distributions and then visualize them in a 3D reservoir model. The 3D seismic data analysis revealed the presence of a clear seismic anomaly geobody (GB) that has never been penetrated by any well. The sedimentological analysis for the well adjacent to the GB indicated a deep-water depositional environment as turbidites surrounded by deep-water mud dominated facies. The Upper Palaeocene interval in the study area was subdivided based on the depositional facies and seismic stratigraphy into eight zones that were used to build the reservoir model framework. According to the porosity permeability relationships, the carbonate facies has been classified into five E-Facies, that is, soft highly argillaceous limestone, hard argillaceous limestone, porous limestone (<20% porosity, and >30% shale volume), medium quality limestone (10–20% porosity, and >30% shale volume) and tight limestone (<10% porosity, and >30% shale volume). The rock physics and inversion feasibility analysis indicated that the acoustic impedance (AI) can be used to predict the porosity but not the lithology or the fluid content. The Bayesian classification has shown excellent results in predicting and modelling the reservoir facies distribution within the study area, utilizing the integration of gross depositional maps (GDEs), wells and seismic data. The reservoir quality of the GB was predicted by using the post-stack seismic inversion, which indicated a high porosity interval (25%–30%). Moreover, the statistical analysis integrated with the well and seismic data was used to predict the GB permeability. The predicted permeability was reasonably high (40–60 mD). The final E-facies show an excellent match with the input well data and an excellent match with the blind wells that were used for result quality control (QC) with higher vertical resolution. The developed model can be used as a guide for de-risking the studied GB hydrocarbon potential in the studied basin, and it can be applied in other similar geological conditions worldwide for exploring underexplored reservoirs and de-risking their hydrocarbon potential.

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来源期刊
Geological Journal
Geological Journal 地学-地球科学综合
CiteScore
4.20
自引率
11.10%
发文量
269
审稿时长
3 months
期刊介绍: In recent years there has been a growth of specialist journals within geological sciences. Nevertheless, there is an important role for a journal of an interdisciplinary kind. Traditionally, GEOLOGICAL JOURNAL has been such a journal and continues in its aim of promoting interest in all branches of the Geological Sciences, through publication of original research papers and review articles. The journal publishes Special Issues with a common theme or regional coverage e.g. Chinese Dinosaurs; Tectonics of the Eastern Mediterranean, Triassic basins of the Central and North Atlantic Borderlands). These are extensively cited. The Journal has a particular interest in publishing papers on regional case studies from any global locality which have conclusions of general interest. Such papers may emphasize aspects across the full spectrum of geological sciences.
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