Relative Permeability Characteristics and Wetting Behavior of Supercritical CO<sub>2</sub> Displacing Water and Remaining Oil for Carbonate Rocks at Reservoir Conditions

Zhou, Xianmin; AlOtaibi, Fawaz; Kokal, Sunil

doi:10.1021/acs.energyfuels.9b01053

Cited by 24 publications

(11 citation statements)

References 42 publications

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“…In order to characterize the time-varying phenomenon, some approximate methods are proposed. The segmental simulation method has been proposed [24][25][26][27][28][29], which divides the simulation process into several time intervals and approximates time varying by setting different property values in each time interval. This method has a discontinuous calculation process and convergence problem.…”

Section: Introductionmentioning

confidence: 99%

Remaining Oil Distribution and Development Strategy for Offshore Unconsolidated Sandstone Reservoir at Ultrahigh Water-Cut Stage

et al. 2022

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Due to the influence of long-term waterflooding, the reservoir physical properties and percolation characteristics tend to change greatly in offshore unconsolidated sandstone reservoirs at ultrahigh water-cut stage, which can affect the remaining oil distribution. Remaining oil characterization and proper development strategy-making are of vital importance to achieve high-efficiency development of mature reservoirs. The present numerical simulation method is difficult to apply in reservoir development due to the problems of noncontinuous characterization and low computational efficiency. Based on the extended function of commercial numerical simulator, the time-varying equivalent numerical simulation method of reservoir physical properties was established, and the research of numerical simulation of X offshore oilfield with 350,000 effective grids was completed. The results show that the time-varying reservoir properties have a significant impact on the distribution of remaining oil in ultrahigh water-cut reservoir. Compared with the conventional numerical simulation, the remaining oil at the top of main thick reservoir in X oilfield has increased by 18.5% and the remaining oil in the low-permeability zone at the edge of the nonmain reservoir has increased by 27.3%. The data of coring well and the implementation effect of measures in the X oilfield are consistent with the recognition of numerical simulation, which proves the rationality of numerical simulation results. The new method is based on a mature commercial numerical simulator, which is easy to operate and has reliable results.

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Section: Introductionmentioning

confidence: 99%

Remaining Oil Distribution and Development Strategy for Offshore Unconsolidated Sandstone Reservoir at Ultrahigh Water-Cut Stage

et al. 2022

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“…On the other hand, a distribution of remaining oil after displacement tests is another important issue for an EOR process in tight oil reservoirs. Zhou et al applied a relative permeability method to predict the remaining oil distribution after CO 2 miscible flooding . Zhao et al adopted a mobility control method to improve a swept volume of a CO 2 injection process and simulated distributions of CO 2 in different heterogeneous reservoirs …”

Section: Introductionmentioning

confidence: 99%

“…Zhou et al applied a relative permeability method to predict the remaining oil distribution after CO 2 miscible flooding. 26 Zhao et al adopted a mobility control method to improve a swept volume of a CO 2 injection process and simulated distributions of CO 2 in different heterogeneous reservoirs. 27 In this article, an experimental investigation on the recovery performance of tight oil reservoirs at pore scale is first investigated.…”

Section: Introductionmentioning

confidence: 99%

Pore-Scale Movability Evaluation for Tight Oil Enhanced Oil Recovery Methods Based on Miniature Core Test and Digital Core Construction

Dong

Chen

Hou

et al. 2020

Ind. Eng. Chem. Res.

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The movability of micro-remaining oil in microscale pores in tight reservoirs directly affects the recoverability of a reservoir fluid. Currently, core displacement and digital cores have been applied for the reservoir fluid movability and microstructure visualization. In this study, we present a practical framework for the pore-scale movability of tight oil, which combines core displacement tests and digital cores on real tight core samples. In this framework, the core displacement tests and miniature core displacement tests using three different displacement methods (water flooding, CH 4 flooding, and CO 2 flooding) are first performed. Then, through a series of CT (computed tomography) scanning results on the core displacement tests, a digital core model is constructed, and a distribution of micro-remaining oil is experimentally investigated. By combining the results of the miniature core displacement tests and the digital core model, the types and movability of tight oil at different times for the three methods are obtained. These results indicate that the remaining tight oil at pore scale can be classified into three different categories according to a shape factor (S) of the remaining oil, including block-like oil (4.85 > S > 1), flat-like oil (12.22 > S > 4.85) and film-like oil (S > 12.22). From CT scanning results, the method of water flooding can effectively unlock the type of block-like oil, while CH 4 flooding and CO 2 flooding can produce flat-like and film-like oil. Furthermore, CO 2 flooding can significantly unlock more film-like oil than CH 4 flooding.

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“…The technology is dedicated to measuring the 1 H relaxation times, both longitudinal (T 1 ) as well as transverse (T 2 ) and occasionally diffusivity . The resolved NMR spectra can help to estimate a wide variety of petrophysical reservoir properties such as porosity, , permeability, wettability, and viscosity of crude oil …”

Section: Introductionmentioning

confidence: 99%

“…4 The technology is dedicated to measuring the 1 H relaxation times, both longitudinal (T 1 ) as well as transverse (T 2 ) and occasionally diffusivity. 5 The resolved NMR spectra can help to estimate a wide variety of petrophysical reservoir properties such as porosity, 6,7 permeability, 8 wettability, 9 and viscosity of crude oil. 10 The estimation of crude oil is one of the unique outputs that NMR well logging tools can potentially provide by the interpretation of T 2 -relaxation signals and their T 2 -distributions.…”

Section: Introductionmentioning

confidence: 99%

NMR-Responsive Paramagnetic [M-EDTA] (M = Fe³⁺, Mn²⁺, Cu²⁺) Complexes to Differentiate T₂-Distribution Signals of Crude Oil and Brine

et al. 2019

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Nuclear magnetic resonance (NMR) well logging tools are being commercially utilized for the characterization of various fluids confined within reservoir rocks. Conventional NMR T2distribution measurements are unable to quantify the actual fractions of crude oil and brine simultaneously present in the reservoir rocks. Herein, we reported NMR responsive paramagnetic [M-EDTA] (M = Fe 3+ , Mn 2+ , Cu 2+) complexes having the capability to differentiate NMR T2distribution signals coming from crude oil and brine by accelerating the water (1 H) relaxation. The formation of these [Fe-EDTA]-, [Mn-EDTA] 2and [Cu-EDTA] 2complexes was explored by UVvisible spectroscopy, and their chemical stability in brine solution was monitored by measuring the change in percent transmittance and backscattering intensities with time. Spin-spin (T2) relaxation signals and T2-distribution spectra of various carbonate and sand packs were recorded. The separation of NMR T2-distribution signals was achieved using the optimized concentration of synthesized paramagnetic complexes. The separation of NMR T2-distribution signals with optimum concentration of complexes and their long-term chemical stability in brine solution suggest them to be commercially reliable contrast agents for the characterization of various rock fluids confined in the oil reservoirs.

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Relative Permeability Characteristics and Wetting Behavior of Supercritical CO₂ Displacing Water and Remaining Oil for Carbonate Rocks at Reservoir Conditions

Cited by 24 publications

References 42 publications

Remaining Oil Distribution and Development Strategy for Offshore Unconsolidated Sandstone Reservoir at Ultrahigh Water-Cut Stage

Remaining Oil Distribution and Development Strategy for Offshore Unconsolidated Sandstone Reservoir at Ultrahigh Water-Cut Stage

Pore-Scale Movability Evaluation for Tight Oil Enhanced Oil Recovery Methods Based on Miniature Core Test and Digital Core Construction

NMR-Responsive Paramagnetic [M-EDTA] (M = Fe³⁺, Mn²⁺, Cu²⁺) Complexes to Differentiate T₂-Distribution Signals of Crude Oil and Brine

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Relative Permeability Characteristics and Wetting Behavior of Supercritical CO2 Displacing Water and Remaining Oil for Carbonate Rocks at Reservoir Conditions

Cited by 24 publications

References 42 publications

Remaining Oil Distribution and Development Strategy for Offshore Unconsolidated Sandstone Reservoir at Ultrahigh Water-Cut Stage

Remaining Oil Distribution and Development Strategy for Offshore Unconsolidated Sandstone Reservoir at Ultrahigh Water-Cut Stage

Pore-Scale Movability Evaluation for Tight Oil Enhanced Oil Recovery Methods Based on Miniature Core Test and Digital Core Construction

NMR-Responsive Paramagnetic [M-EDTA] (M = Fe3+, Mn2+, Cu2+) Complexes to Differentiate T2-Distribution Signals of Crude Oil and Brine

Contact Info

Product

Resources

About

Relative Permeability Characteristics and Wetting Behavior of Supercritical CO₂ Displacing Water and Remaining Oil for Carbonate Rocks at Reservoir Conditions

NMR-Responsive Paramagnetic [M-EDTA] (M = Fe³⁺, Mn²⁺, Cu²⁺) Complexes to Differentiate T₂-Distribution Signals of Crude Oil and Brine