Numerical Simulation of a CT-Scanned Counter-Current Flow Experiment

Self Cite

The purpose of this study is to investigate factors that affect the formation of fluid banks during gravity-driven counter-current flow in porous media. To our knowledge, development of a fluid bank has been observed in only one previous counter-current flow experiment, although there are some hints of fluid banks in other experiments. We have undertaken experimental and simulation studies to confirm the presence of such banks and to delineate factors which enhance or inhibit their formation. Experiments were performed using glass bead packs and X-ray Computed Tomography to monitor saturation distribution as a function of time. The simulation approach considers saturation history at every point in the sample, defining conditions at each time point from hysteresis in capillary pressure and relative permeability. The model proved to reproduce experimental observations accurately. The experiments and associated model show that a minimal vertical sample height is needed for the development of a fluid bank. In addition, round sample boundaries and higher average nonwetting phase saturation tend to prevent the formation of a bank. The validated model can improve our ability to predict and optimize counter-current flow processes, both in the laboratory and in the field (e.g. exploration and hydrocarbon extraction).

Section: History-dependent Modelingmentioning

confidence: 99%

Section: History-dependent Modelingmentioning

confidence: 99%

Section: History-dependent Modelingmentioning

confidence: 99%

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Experimental Conditions Favoring the Formation of Fluid Banks during Counter-Current Flow in Porous Media

Karpyn

Grader

et al. 2006

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“…Therefore, to correctly model oil recovery processes, capillary pressure hysteresis has to be taken into consideration with a specified saturation history for each gridblock. The development of such a model, called history-dependent modeling, is given by Li et al (2005). In this modeling method, different capillary pressure (scanning) curves are assigned to different locations according to the initial saturation and saturation history, and different relative permeability curves are assigned to the different flow regimes.…”

Section: Hysteresis Of Parameters Controlling Counter-current Flowmentioning

confidence: 99%

Modeling the Formation of Fluid Banks During Counter-Current Flow in Porous Media

Karpyn

Halleck

et al. 2006

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Fluid banks sometimes form during gravity-driven counter-current flow in certain natural reservoir processes. Prediction of flow performance in such systems depends on our understanding of the bank-formation process. Traditional modeling methods using a single capillary pressure curve based on a final saturation distribution have successfully simulated counter-current flow without fluid banks. However, it has been difficult to simulate counter-current flow with fluid banks. In this paper, we describe the successful saturation-history-dependent modeling of counter-current flow experiments that result in fluid banks. The method used to simulate the experiments takes into account hysteresis in capillary pressure and relative permeabilities. Each spatial element in the model follows a distinct trajectory on the capillary pressure versus saturation map, which consists of the capillary hysteresis loop and the associated capillary pressure scanning curves. The new modeling method successfully captured the formation of the fluid banks observed in the experiments, including their development with time. Results show that bank formation is favored where the p c -versus-saturation slope is low. Experiments documented in the literature that exhibited formation of fluid banks were also successfully simulated.

“…Comparing with NMR, it will cost less money for CT scanning while ensuring study result. From the 1980s onwards, petroleum engineers began to use CT technology in core analysis to determine porosity, internal structure, and the change of fluid saturation in the course of displacement (Walsh and Withjack 1994;Schembre and Kovscek 2003;Li et al 2005;Du et al 2007).…”

mentioning

confidence: 99%

Computerized Tomography Study of the Microscopic Flow Mechanism of Polymer Flooding

Hou

Zhang³

et al. 2009

The microscopic flow mechanism of polymer flooding was examined using an industrial microfocus computerized tomography system. On the basis of scanned slices acquired in the process of water flooding and polymer flooding, three-dimensional visualization of oil and water distribution in different flooding conditions was achieved with a series of image processing methods, including pre-processing, interpolation, segmentation, and three-dimensional construction, which are effective techniques for both the qualitative description and the quantitative characterization of the microscopic flow mechanism. This study has confirmed the suggestion that the displacement efficiency of polymer flooding is higher than that of water flooding, and effectively revealed the microscopic mechanism of oil recovery in polymer flooding. The water/oil mobility ratio was improved after polymer flooding, which resulted in a break of the "equilibrium" flow field that was formed during water flooding and the redistribution of the regions of oil saturation. The remaining oil was flushed out as the result of the flow redirection and the viscoelastic effect of polymer flooding. Compared to water flooding, polymer flooding increased the microscopic sweep efficiency as well as the microscopic displacement efficiency, and thereby the ultimate oil recovery.