Sensitivity Study of Foam Diversion Processes for Matrix Acidization

Kibodeaux, K.R.; Zeilinger, Sabine C.; Rossen, W.R.

doi:10.2118/28550-ms

Cited by 54 publications

(38 citation statements)

References 30 publications

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“…As a result, pressure gradient increased in these experiments during liquid injection ( Fig. 2.8); all our previous experiments (Kibodeaux et al, 1994;Zeilinger et al, 1995;Rossen and Wang, 1999) had seen a decrease in pressure gradient during liquid injection.…”

Section: Initial Experiments: Water Saturation and Gas Trapping With supporting

confidence: 61%

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Mechanistic Studies of Improved Foam Eor Processes

Rossen¹

2005

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The objective of this research is to widen the application of foam to enhanced oil recovery (EOR) by investigating fundamental mechanisms of foams in porous media. This research is to lay the groundwork for more-applied research on foams for improved sweep efficiency in miscible gas, steam and surfactant-based EOR. Task 1 investigates the pore-scale interactions between foam bubbles and polymer molecules. Task 2 examines the mechanisms of gas trapping, and interaction between gas trapping and foam effectiveness. Task 3 investigates mechanisms of foam generation in porous media.For Task 1, we investigated the interactions of polymers and foam in search of means to stabilize and strengthen foam using polymers, especially in the presence of oil For the polymers (xanthan and partially hydrolyzed polyacrylamide), oils (decane and 37.5° API crude oil), and surfactant (alpha-olefin sulfonate) tested here, it appears from coreflood pressure gradient |∇p| that polymer destabilizes foam modestly, raising water saturation S w and water relative permeability k rw . The increased viscosity of the aqueous phase with polymer partially compensates for the destabilization of foam. For the same polymers and surfactant, polymer does not stabilize foam in the presence of decane or 37.5° API crude oil.Complex behavior, in contradiction to the expected two steady-state strong-foam regimes, was sometimes observed. At the limit of, or in the place of, the high-quality regime, there was sometimes an abrupt jump upwards in |∇p| as though from hysteresis and a change of state. In the low-quality regime, |∇p| was not independent of liquid superficial velocity, but decreased with increasing liquid superficial velocity. This curious behavior in the low-quality regime was also found in studies of CO 2 foam; an explanation was discovered in research on Task 2. Pressure gradient can decrease upon increasing liquid superficial velocity in the low-quality regime because the drag on bubbles decreases as the liquid film between the bubble and the pore wall thickens.A new theory developed for the drag on bubbles moving through tubes suggests that polymer should make foam more shear-thinning than foam without polymer, both in the high-quality and low-quality flow regimes.Regarding Task 2, a new model for gas trapping was incorporated into a foam simulator. In this model, trapped-gas saturation is a function of pressure gradient, fit to DE-FC26-01BC15318 Final Report -4 data for liquid relative permeability following foam injection and the gas relativepermeability curve. This model can fit steady-state data for the two strong-foam flow regimes and in limited trials it also fitted the transition period between foam injection and injection of liquid following foam in coreflood experiments. The simulator would be most helpful in modeling liquid injectivity in SAG foam processes.Coreflood experiments during liquid injection following foam concluded that liquid saturation rose more upon liquid injection; i.e., less gas was trapped during liquid inj...

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Section: Initial Experiments: Water Saturation and Gas Trapping With supporting

confidence: 61%

“…The early modeling work of Kibodeaux et al (1994) concluded that the decline in pressure gradient seen shortly after liquid injection begins reduces the ability of foam to overcome the effects of permeability and divert the flow of liquid in acid-diversion processes.…”

Section: Initial Experiments: Water Saturation and Gas Trapping With mentioning

confidence: 99%

Mechanistic Studies of Improved Foam Eor Processes

Rossen¹

2005

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“…In the otherwise-successful SAG foam field trial in the Snorre field (Martinssen and Vassenden, 1999), low liquid injectivity caused fracturing of the injection well and loss of most of the injected surfactant in the second and third liquid slugs. Low liquid mobility after foam injection is also crucial to the success of foam-acid diversion processes (Kibodeaux et al, 1994).…”

Section: Task 2: Increase Sweep Efficiency With Foam Subtask 21: Mecmentioning

confidence: 99%

“…Previous experiments on liquid injection after foam had been conducted in conjunction with foam-acid diversion for well stimulation (Kibodeaux et al, 1994;Rossen and Wang, 1999). New experiments were conducted in parallel with a simulation study (Cheng et al, 2002).…”

Section: Task 2: Increase Sweep Efficiency With Foam Subtask 21: Mecmentioning

confidence: 99%

Development of More-Efficient Gas Flooding Applicable to Shallow Reservoirs

Rossen¹,

Johns²,

Pope³

2003

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ABSTRACT:The objective of this research is to widen the applicability of gas flooding to shallow oil reservoirs by reducing the pressure required for miscibility using gas enrichment and increasing sweep efficiency with foam. Task 1 examines the potential for improved oil recovery with enriched gases. Subtask 1.1 examines the effect of dispersion processes on oil recovery and the extent of enrichment needed in the presence of dispersion. Subtask 1.2 develops a fast, efficient method to predict the extent of enrichment needed for crude oils at a given pressure. Task 2 develops improved foam processes to increase sweep efficiency in gas flooding. Subtask 2.1 comprises mechanistic experimental studies of foams with N 2 gas. Subtask 2.2 conducts experiments with CO 2 foam. Subtask 2.3 develops and applies a simulator for foam processes in field application.Regarding Task 1, several key results are described in this report relating to subtask 1.1. In particular, we show how for slimtube experiments, oil recoveries do not increase significantly with enrichments greater than the MME. For field projects, however, the optimum enrichment required to maximize recovery on a pattern scale may be different from the MME. The optimum enrichment is likely the result of greater mixing in reservoirs than in slimtubes. In addition, 2-D effects such as channeling, gravity tonguing, and crossflow can impact the enrichment selected. We also show the interplay between various mixing mechanisms, enrichment level, and numerical dispersion. The mixing mechanisms examined are mechanical dispersion, gravity crossflow, and viscous crossflow. UTCOMP is used to evaluate the effect of these mechanisms on recovery for different grid refinements, reservoir heterogeneities, injection boundary conditions, relative permeabilities, and numerical weighting methods including higher-order methods. For all simulations, the reservoir fluid used is a twelve-component oil displaced by gases enriched above the MME.The results for subtask 1.1 show that for 1-D enriched-gas floods, the recovery difference between displacements above the MME and those at or near the MME increases significantly with dispersion. The trend, however, is not monotonic and shows a maximum at a dispersivity (mixing level) of about 4 ft. The trend is independent of relative permeabilities and gas trapping for dispersivities less than about 4 ft. For 2-D enriched gas floods with slug injection, the difference in recovery generally increases as 4 4 dispersion and crossflow increase. The magnitude of the recovery differences is less than observed for the 1-D displacements. Recovery differences for 2-D models are highly dependent on relative permeabilities and gas trapping. For water alternating gas (WAG) injection, the differences in recovery increase slightly as dispersion decreases. That is, the recovery difference is significantly greater with WAG at low levels of dispersion than with slug injection. For the cases examined, the magnitude of recovery difference varies from about 1 to 8 ...

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“…The insight gained into the FDL process is mainly due to co-workers [1994, 2001], who conducted systematic studies using two-stage experiments of foam placement followed by liquid injection. Rossen et al [1994Rossen et al [ , 2001 found that the pressure gradient declines in two steps. The pressure gradient first falls rapidly, but levels off to a value that remains relatively high.…”

Section: Introductionmentioning

confidence: 99%

Gas Trapping During Foamed Flow in Porous Media

Nguyen¹

2011

Computed Tomography - Special Applications

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Sensitivity Study of Foam Diversion Processes for Matrix Acidization

Cited by 54 publications

References 30 publications

Mechanistic Studies of Improved Foam Eor Processes

Mechanistic Studies of Improved Foam Eor Processes

Development of More-Efficient Gas Flooding Applicable to Shallow Reservoirs

Gas Trapping During Foamed Flow in Porous Media

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