Neutron Response Modeling to Track Lean Gas Plume in Recycled Gas Cap Reservoir in Concurrent Gas Cap-Oil Rim Development: A Step Forward

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
R. Reddy, Aditya Ojha, R. Nachiappan, S. Mengal, M. A. Al Hosani, A. A. Al Bairaq, M. Baslaib
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引用次数: 0

Abstract

Gas cap pressure maintenance while developing the associated oil rim is a critical aspect for optimum recovery. Preventing gas cap pressure dropping below dewpoint by injecting lean gas is essential for concurrent gas cap-oil rim development. Reservoir heterogeneity aggravates lean gas override causing preferential movement of lean gas plume. Thus, it is important to track lean gas plume while recycling and understanding the breakthrough potential of lean gas. This paper demonstrates a new workflow to track lean gas plume by estimating phase saturations with a case study from one of the giant oil and gas fields, Onshore, Abu Dhabi. Pulsed neutron capture (PNC) tools are used for reservoir monitoring and surveillance. However, sigma log evaluation is insufficient to derive individual hydrocarbon phase saturations to monitor lean gas plume. Neutron response modeling (NRM) is devised to differentiate between lean and rich gas. NRM is a probabilistic solver with input of mineral and fluid phase parameters into tool response functions in petrophysical evaluation. To distinguish with discrete neutron fluid response between lean and rich gas, pressure/volume/temperature (PVT) data are utilized to derive hydrogen index, capture cross section, thermal decay length, and neutron macro parameters, such as neutron slowing down length and migration length. Neutron response is investigated for lean and rich gas with sensitivity of invasion effects on neutron log by calibrating to core porosity. The response for each phase under thermal neutron and capture modes with corresponding raw neutron log statistics is reviewed in both openhole and casedhole environments in known lean/rich gas intervals. Thirty-five wells spread across gas cap and oil leg with quality neutron log data are modeled and individual phase saturations are estimated. The target reservoir is under development with over three decades of lean gas injection to support oil production. NRM results and phase saturations are validated with recent formation sampling, which enhanced the confidence in the overall workflow. Later, the results are verified to be in excellent agreement with lean gas injection and production history of the target reservoir. The identified movement of lean gas highlights nonuniform geology and gravity segregation of injected lean gas into upper members of the target reservoir. The results also emphasized the need for better injection support to lower members of the target reservoir where gas cap development is ongoing. The solution presented is unique, particularly for lean gas injection projects by utilizing PVT for NRM based on neutron transport mechanism in pore fluids. Existing workflows require a special nuclear modeling platform with computationally expensive processing on data sets acquired using advanced logging technology. In spite of these prerequisites, existing workflows are not able to distinguish lean gas over rich gas. This paper effectively demonstrates NRM workflow distinguishing lean gas plume from rich gas using neutron logs and reveals compelling reservoir management insights. The sensitivity studies and practicality of this workflow highlight the fundamental importance of neutron logs in mature fields.
气顶-油环同步开发中再生气顶油藏贫气羽流跟踪的中子响应模型研究进展
在开发伴生油环的同时保持气顶压力是实现最佳采收率的关键因素。通过注入贫气防止气顶压力降至露点以下是气顶油环同步开发的关键。储层非均质性加剧了贫气覆盖,导致贫气羽流优先运动。因此,在回收利用的同时跟踪贫气羽流并了解贫气的突破潜力是非常重要的。本文以阿布扎比陆上一个大型油气田为例,介绍了一种通过估算相饱和度来跟踪贫气羽流的新工作流程。脉冲中子捕获(PNC)工具用于油藏监测和监视。然而,σ测井评价不足以得出单个烃相饱和度来监测贫气羽流。中子响应模型(NRM)用于区分贫气和富气。在岩石物理评价中,NRM是一种将矿物和流体相参数输入到工具响应函数中的概率求解器。为了区分贫气和富气的离散中子流体响应,利用压力/体积/温度(PVT)数据推导出氢指数、俘获截面、热衰变长度以及中子慢化长度和迁移长度等中子宏观参数。通过对岩心孔隙度的标定,研究了贫气和富气对中子测井侵入效应的敏感性。在已知贫/富气层段的裸眼和套管井环境中,利用相应的原始中子测井统计数据,回顾了热中子和捕获模式下每个相的响应。利用高质量的中子测井资料对分布在气顶和油腿上的35口井进行了建模,并估计了各个相的饱和度。目标储层正在开发中,已经进行了30多年的贫气注入以支持石油生产。通过最近的地层采样验证了NRM结果和相饱和度,从而增强了对整个工作流程的信心。随后,结果与目标储层的注贫气和生产历史非常吻合。识别出的贫气运动凸显了注入到目标储层上部的贫气地质不均匀性和重力偏析性。研究结果还强调了对正在进行气顶开发的目标储层下部进行更好的注入支持的必要性。提出的解决方案是独一无二的,特别是在贫气注入项目中,利用PVT进行基于孔隙流体中中子输运机制的NRM。现有的工作流程需要一个特殊的核建模平台,对使用先进测井技术获得的数据集进行处理,计算成本很高。尽管有这些先决条件,现有的工作流程无法区分贫气和富气。本文有效地展示了利用中子测井区分贫气羽流和富气羽流的NRM工作流程,并揭示了令人信服的油藏管理见解。该工作流程的敏感性研究和实用性凸显了中子测井在成熟油田中的基础性重要性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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