The impacts of CO2 flooding on crude oil stability and recovery performance

Hartono, Kartika F.; Permadi, Asep K.; Siagian, Ucok W. R.; Hakim, Andri L. L.; Paryoto, Sumadi; Resha, Ahlul H.; Adinugraha, Yudistira; Pratama, Egi A.

doi:10.1007/s13202-023-01699-y

Cited by 6 publications

(2 citation statements)

References 58 publications

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“…This implies that the impurities in CO 2 gas would probably play a non-negligible role in causing this variation. Besides, some specific components (e.g., asphaltene) in crude oil could also influence dissolution and mixing of CO 2 , resulting in the weakening of correlation at high temperature. − All of these indicate that the correlation of MMP with temperature could be affected by some complex components in both oil and gas. Although reservoir temperature is the most significant influencing factor for MMP, the insufficient consideration of the types of components in oil and gas can also potentially cause the notable predictive deviation of MMP.…”

Section: Resultsmentioning

confidence: 99%

Unveiling the Effect of Complex Components on CO₂-Oil Minimum Miscibility Pressure: Insights from Deep Convolutional Neural Networks

Fan,

Yao,

Fan

et al. 2024

Energy Fuels

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The determination of the minimum miscibility pressure (MMP) between CO 2 and oil holds significant importance in the analysis and modeling of CO 2 miscible flooding processes. Several components in both CO 2 and crude oil could exert complex effects on MMP values. To address this issue in depth, we designed a novel convolutional neural network to investigate the effect of some complex components in CO 2 and oil on MMP in the context of CO 2 enhanced oil recovery. Our results yield valuable insights: (1) employing a multilayer deep convolutional structure, our neural network (NN) model is capable of deeply understanding the relationships of MMP with the contents of various components, extending the type and number of the considered components. Using temperature and the contents of totally 11 components, which do not show obvious cross-correlation, as inputs, the established NN model is demonstrated to attain high prediction precision; (2) temperature has the highest positive correlation with MMP, but the correlation would diminish beyond a certain temperature value. Among the analyzed components, molecular weight of C 7+ and volatile components in oil as well as that of nitrogen, methane, and C 6+ in CO 2 gas show positive correlation with MMP, while mole percentages of intermediate light and heavy hydrocarbons in oil as well as that of hydrogen sulfide, intermediate light hydrocarbon, and C 5 in CO 2 gas exhibit negative correlation. Comparatively, MMP demonstrates heightened sensitivity to variations in molecular weight of C 7+ in oil, while displaying less susceptibility to changes in mole percentage of methane, C 2 −C 4 , and C 5 in gas. The elucidated correlations and sensitivities between MMP and these 12 attributes hold significant potential for future advancements in deriving and refining empirical prediction formulas for MMP.

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Section: Resultsmentioning

confidence: 99%

Unveiling the Effect of Complex Components on CO₂-Oil Minimum Miscibility Pressure: Insights from Deep Convolutional Neural Networks

Fan,

Yao,

Fan

et al. 2024

Energy Fuels

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“…The operating pressures used in the displacement process are 1000 psi, 2000 Psi, 3000 psi, 4000 psi, and 5000 psi. The detail experimental procedures of the dynamic slim test refer to the author previous work [2]. The polarity components of the oil produced by CO2 displacement, which include saturate, aromatic, resin, and asphaltene fractions (SARA), were further analyzed to examine the impact of dense CO2's extraction of the hydrocarbon components.…”

Section: Methodsmentioning

confidence: 99%

The characteristics of produced oils in the miscible CO₂ displacement process

Hartono,

Permadi,

Paryoto

et al. 2024

IOP Conf. Ser.: Earth Environ. Sci.

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CO2 flooding is an effective technique for enhancing oil recovery by changing the hydrocarbon fluid’s characteristics. One of the fundamental mechanisms of the interaction between CO2 and hydrocarbon fluid by miscible CO2 injection is the extraction phenomenon of the hydrocarbon components by CO2. It results in altered produced and residual oil characteristics. This study aims to examine the characterizations of produced oil during the process of CO2 displacement. It is critical to anticipate any issues that can arise from miscible CO2 flooding, such as asphaltene deposition. A light-dead oil sample from an Indonesian oil field was used in this investigation. The miscible CO2 displacement process was conducted by a slim tube experiment at operating temperature of 90°C and 70°C, which represents the reservoir and surface temperature, respectively. The properties of produced oil were further characterized by analyzing the composition based on its polarity, including saturate, aromatic, resin, and asphaltene. The results show that increasing injection pressures decrease resin and asphaltene fractions in produced oil. Furthermore, the proportions of asphaltene and resin fractions in the crude sample exhibit a significant decrease when conducted at a lower temperature in comparison to when carried out at a higher temperature. This study helps to explain how the displacement process by CO2 affects the properties of the produced oil.

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Investigating the CO₂ injection and the performance of nanoparticles in preventing formation damage at different pressures and concentrations

Talebi,

Shafiei,

Escrochi

et al. 2024

Can J Chem Eng

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Asphaltene deposition is one of the main challenges during CO2 injection (miscible or immiscible) into reservoirs. Asphaltene deposition reduces the porosity and permeability of reservoir rock and changes its wettability to strongly oil‐wet. In this article, to control the asphaltene deposition during CO2 injection the use of direct asphaltene inhibitors (Al2O3 and Fe3O4) in reservoir conditions. In this research, nanoparticle screening (to investigate its significance in reducing asphaltene precipitation) has been done and it can be stated that Al2O3 nanoparticle will perform better effectivity than Fe3O4 nanoparticle. After that, by using effective nanoparticles (Al2O3) in different concentrations (1000 and 2000 ppm), the amount of asphaltene deposition during CO2 injection has been investigated. The obtained results show that increasing the injection pressure (from immiscible to miscible) causes an increase in asphaltene deposition and the use of nanoparticles will reduce the amount of asphaltene deposition.

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The impacts of CO2 flooding on crude oil stability and recovery performance

Cited by 6 publications

References 58 publications

Unveiling the Effect of Complex Components on CO₂-Oil Minimum Miscibility Pressure: Insights from Deep Convolutional Neural Networks

Unveiling the Effect of Complex Components on CO₂-Oil Minimum Miscibility Pressure: Insights from Deep Convolutional Neural Networks

The characteristics of produced oils in the miscible CO₂ displacement process

Investigating the CO₂ injection and the performance of nanoparticles in preventing formation damage at different pressures and concentrations

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The impacts of CO2 flooding on crude oil stability and recovery performance

Cited by 6 publications

References 58 publications

Unveiling the Effect of Complex Components on CO2-Oil Minimum Miscibility Pressure: Insights from Deep Convolutional Neural Networks

Unveiling the Effect of Complex Components on CO2-Oil Minimum Miscibility Pressure: Insights from Deep Convolutional Neural Networks

The characteristics of produced oils in the miscible CO2 displacement process

Investigating the CO2 injection and the performance of nanoparticles in preventing formation damage at different pressures and concentrations

Contact Info

Product

Resources

About

Unveiling the Effect of Complex Components on CO₂-Oil Minimum Miscibility Pressure: Insights from Deep Convolutional Neural Networks

Unveiling the Effect of Complex Components on CO₂-Oil Minimum Miscibility Pressure: Insights from Deep Convolutional Neural Networks

The characteristics of produced oils in the miscible CO₂ displacement process

Investigating the CO₂ injection and the performance of nanoparticles in preventing formation damage at different pressures and concentrations