Chemical-assisted MMP reduction on methane-oil systems: Implications for natural gas injection to enhanced oil recovery

IF 4.2 Q2 ENERGY & FUELS

Petroleum Pub Date : 2024-03-01 DOI:10.1016/j.petlm.2022.07.001

Mohamed Almobarak , Matthew B. Myers , Colin D. Wood , Yongbing Liu , Ali Saeedi , Quan Xie

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引用次数: 0

Abstract

Miscible natural gas injection is widely considered as a practical and efficient enhanced oil recovery technique. However, the main challenge in this process is the high minimum miscibility pressure (MMP) between natural gas and crude oil, which limits its application and recovery factor, especially in high-temperature reservoirs. Therefore, we present a novel investigation to quantify the effect of chemical-assisted MMP reduction on the oil recovery factor. Firstly, we measured the interfacial tension (IFT) of the methane-oil system in the presence of chemical or CO₂ to calculate the MMP reduction at a constant temperature (373K) using the vanishing interfacial tension (VIT) method. Afterwards, we performed three coreflooding experiments to quantify the effect of MMP reduction on the oil recovery factor under different injection scenarios.

The interfacial tension measurements show that adding a small fraction (1.5 wt%) of the tested surfactant (SOLOTERRA ME-6) achieved 9% of MMP reduction, while adding 20 wt% of CO₂ to the methane yields 13% of MMP reduction. Then, the coreflooding results highlight the significance of achieving miscibility during gas injection, as the ultimate recovery factor increased from 65.5% under immiscible conditions to 77.2% using chemical-assisted methane, and to 79% using gas mixture after achieving near miscible condition. The results demonstrate the promising potential of the MMP reduction to significantly increase the oil recovery factor during gas injection. Furthermore, these results will likely expand the application envelop of the miscible gas injection, in addition to the environmental benefits of utilizing the produced gas by re-injection/recycling instead of flaring which contributes to reducing the greenhouse gas emissions.

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化学辅助减少甲烷-石油系统中的 MMP：天然气注入提高石油采收率的意义

混相天然气注入被广泛认为是一种实用高效的提高石油采收率技术。然而，这一工艺面临的主要挑战是天然气与原油之间的最低混溶压力（MMP）过高，从而限制了其应用和采收率，尤其是在高温油藏中。因此，我们进行了一项新的研究，以量化化学辅助降低 MMP 对采油率的影响。首先，我们测量了甲烷-石油体系在化学剂或二氧化碳存在下的界面张力（IFT），利用界面张力消失法（VIT）计算了恒温（373K）下的 MMP 降幅。界面张力测量结果表明，添加一小部分（1.5 wt%）被测表面活性剂（SOLOTERRA ME-6）可使 MMP 降低 9%，而在甲烷中添加 20 wt% 的 CO2 可使 MMP 降低 13%。然后，岩心注水结果凸显了在注气过程中实现混溶的重要性，因为最终采收率从不相溶条件下的 65.5% 提高到了使用化学辅助甲烷条件下的 77.2%，而在实现接近混溶条件后，使用混合气体条件下的采收率提高到了 79%。这些结果表明，在注气过程中，减少甲烷的生成量可显著提高石油采收率。此外，这些结果很可能会扩大混相注气的应用范围，而且通过重新注入/回收利用而不是燃烧来利用所产生的气体也会带来环境效益，有助于减少温室气体排放。

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

Petroleum Earth and Planetary Sciences-Geology

CiteScore

9.20

自引率

0.00%

发文量

审稿时长

124 days

期刊介绍： Examples of appropriate topical areas that will be considered include the following: 1.comprehensive research on oil and gas reservoir (reservoir geology): -geological basis of oil and gas reservoirs -reservoir geochemistry -reservoir formation mechanism -reservoir identification methods and techniques 2.kinetics of oil and gas basins and analyses of potential oil and gas resources: -fine description factors of hydrocarbon accumulation -mechanism analysis on recovery and dynamic accumulation process -relationship between accumulation factors and the accumulation process -analysis of oil and gas potential resource 3.theories and methods for complex reservoir geophysical prospecting: -geophysical basis of deep geologic structures and background of hydrocarbon occurrence -geophysical prediction of deep and complex reservoirs -physical test analyses and numerical simulations of reservoir rocks -anisotropic medium seismic imaging theory and new technology for multiwave seismic exploration -o theories and methods for reservoir fluid geophysical identification and prediction 4.theories, methods, technology, and design for complex reservoir development: -reservoir percolation theory and application technology -field development theories and methods -theory and technology for enhancing recovery efficiency 5.working liquid for oil and gas wells and reservoir protection technology: -working chemicals and mechanics for oil and gas wells -reservoir protection technology 6.new techniques and technologies for oil and gas drilling and production: -under-balanced drilling/gas drilling -special-track well drilling -cementing and completion of oil and gas wells -engineering safety applications for oil and gas wells -new technology of fracture acidizing