Novel Techniques for Measuring Heavy-Oil Fluid Properties

Goodarzi, N.N.; Bryan, J.; Thuy, An; Kantzas, Apostolos

doi:10.2118/97803-pa

Cited by 18 publications

(4 citation statements)

References 23 publications

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“…This implies that gas leaves solution all over the core, which was also previously measured in bulk liquid studies 15 . This is a function of the relatively small scale of these experiments; in longer core systems gas will only leave solution in the regions close to the production end of the core 16 .…”

Section: Secondary Waterfloodsupporting

confidence: 67%

Mechanisms of Heavy Oil Recovery by Low Rate Waterflooding

Mai¹,

Kantzas²

2008

Canadian International Petroleum Conference

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At the conclusion of primary heavy oil production, significant volumes of oil still remain in the reservoir under depleted reservoir pressure. Waterfloods are often considered for additional oil recovery. It is accepted that conventional oil waterflooding theory is not applicable for heavy oil. However, there is a lack of understanding of how waterfloods should perform in these reservoirs, particularly after water breakthrough. In this study, waterfloods were performed at multiple rates in cores containing heavy oil and connate water. In some cores oil was initially free of solution gas, and waterfloods were a primary recovery process. In other cores, waterfloods were performed after primary production. Experiments were performed in linear systems for a highviscosity oil (11,500 mPa⋅s), at different injection rates. The influence of viscous and capillary forces is studied in primary vs. secondary recovery systems. A common misconception is that capillary forces are negligible in heavy oil; however this work shows that these forces are significant, and that water imbibition after water breakthrough can lead to improved oil recovery in both primary and secondary waterfloods. PETROLEUM SOCIETY

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Section: Secondary Waterfloodsupporting

confidence: 67%

Mechanisms of Heavy Oil Recovery by Low Rate Waterflooding

Mai¹,

Kantzas²

2008

Canadian International Petroleum Conference

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“…In previous work, however, it has been observed that oil AI can be related to the oil geometric mean relaxation time (16,17) since both vary monotonically with oil viscosity. Therefore, the de-convoluted oil average relaxation times were calculated and related to oil AI through the following empirical correlation (18) : where RHI = oil AI divided by water AI at the same temperature and T 2gm = geometric mean oil relaxation time. Figure 11 shows the NMR water and oil saturation predictions, plotted against the measured DS values obtained for sister samples.…”

Section: Oil Sands Characterizationmentioning

confidence: 99%

Advances in Magnetic Resonance Relaxometry for Heavy Oil and Bitumen Characterization

Kantzas

2009

Journal of Canadian Petroleum Technology

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This paper offers a summary of the advances in heavy oil and bitumen reservoir characterization and fluid stream monitoring using low field magnetic resonance tools. Both laboratory and field advances are presented. Although the bulk of the work discussed was performed in our laboratory, a selection of other pertinent technologies is also presented. This overview aims at offering the reader a quick reference of what has been achieved in the past ten years and it is hoped that it will be used as a guide for future development in this area.

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“…Some complementary means have been used to achieve more detailed information on the target fluid properties. CT scanning on long-core/sandpacked models has been utilized to determine the density field of the testing fluids contained in specialized holders. − The density field scanning quality depends on the accuracy and frequency of the scanning. Microfluidic systems have been widely used in petroleum and chemical engineering, which offers a direct way of observation of phase behavior .…”

Section: Introductionmentioning

confidence: 99%

Nonequilibrium Exsolution Kinetics of Hydrocarbon Solvents in Heavy Oil

Wang,

Zeng,

Torabi

et al. 2024

Energy Fuels

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Nonequilibrium exsolution kinetics of methane and propane in heavy oil were studied through visual experimentations and continuum simulations. Experimentally, novel Constant Composition Expansion (CCE) tests, combined with a micromodel to visualize the bubbly oil flow, were fulfilled in pressure−volume− temperature (PVT) cells. Two schemes were applied, namely, constant volume extraction (CVE) and stepwise pressure depletion (SPD). From the pressure measurement of CVE, methane first went through a pressure-declining period due to hysteresis of exsolution and later a pressure-maintaining period under a balance between exsolution and volume expansion rate. Meanwhile, the pressure of the propane system dropped rapidly and rebounded back to a constant pressure for a long period of time due to a higher solubility than methane. Compared with equilibrium state, the solvent exsolution of both live oils were always under nonequilibrium. Bubbly oil flow was visually observed to determine the range of pseudobubble point pressure. From the volume expansion behavior from the SPD tests, both methane-and propane-based live oil systems present a close-to-linear relationship between volume and time at each pressure drawdown level before reaching equilibrium. This facilitates the quantification of exsolution rate under given pressure. Numerically, a simulation platform to calculate nonequilibrium exsolution kinetics has been built. The feasibility of the simulator is verified through simulating literature data with various pressure data ranges. The exsolution rates have been achieved by history matching the CVE and SPD tests. For CVE tests, methane shows a higher exsolution rate (1 × 10 −4 to 1 × 10 −2 min −1 ) than propane (1 × 10 −6 to 1 × 10 −3 min −1 ) under the same volume expansion rate, indicating a higher tendency to exsolve and form foamy oil. Propane tends to stay in heavy oil due to high solubility. The exsolution rates of the stable-pressure period present a power relationship with volume expansion rate for both live oils. For SPD tests, methane presents a similar range of exsolution rates (1 × 10 −5 to 1 × 10 −4 min −1 ) as propane under similar P/P sat ratios with pre-existing free gas phase. Compared to tests conducted by a sudden pressure drawdown scheme, pre-existing gas cap yields lower exsolution rates due to smaller chemical potential between phases. SPD tests also verify faster exsolution kinetics for methane than propane.

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Novel Techniques for Measuring Heavy-Oil Fluid Properties

Cited by 18 publications

References 23 publications

Mechanisms of Heavy Oil Recovery by Low Rate Waterflooding

Mechanisms of Heavy Oil Recovery by Low Rate Waterflooding

Advances in Magnetic Resonance Relaxometry for Heavy Oil and Bitumen Characterization

Nonequilibrium Exsolution Kinetics of Hydrocarbon Solvents in Heavy Oil

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