Multiscale Study of Impact of Wettability, Mineralogy, and Pore Topology on Fluid Displacement by Surfactants, Microemulsions, and Nanofluids in Heterogeneous Rocks

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ISBN 13 : 9781658425513
Total Pages : 206 pages
Book Rating : 4.4/5 (255 download)

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Book Synopsis Multiscale Study of Impact of Wettability, Mineralogy, and Pore Topology on Fluid Displacement by Surfactants, Microemulsions, and Nanofluids in Heterogeneous Rocks by : Tianzhu Qin

Download or read book Multiscale Study of Impact of Wettability, Mineralogy, and Pore Topology on Fluid Displacement by Surfactants, Microemulsions, and Nanofluids in Heterogeneous Rocks written by Tianzhu Qin and published by . This book was released on 2019 with total page 206 pages. Available in PDF, EPUB and Kindle. Book excerpt: Chemical additives such as surfactants, microemulsions (MEs), and nanofluids are often added to brine to enhance oil recovery or remediate aquifers contaminated by non-aqueous phase liquids (NAPLs). The goal of this fundamental study was to examine the effect of these additives on multiscale oil displacements in six aged sandstones and carbonates (Berea, Bentheimer, Tensleep, Arkose, Edwards, and Fond Du Lac) and identify the test conditions in which chemicals exhibit superior performance. Several mechanisms such as reduction in NAPL/brine interfacial tension (IFT), oil emulsification, reduced NAPL layer thickness, and wettability alteration were responsible for the recovery enhancement. Macroscale tests indicated that the solubilization capacity of MEs was superior in Tensleep compared to Berea and Edwards due to MEs’ unique ability to penetrate microporous dolomites and alter their wettability. This solubilization ability was confirmed by x-ray microtomography experiments with Arkose where MEs were able to restore the wettability of pore surfaces by penetrating rough carbonate cements and desorbing asphaltenes in the form of small emulsified NAPL droplets. The surfactant formulation was further optimized to improve MEs’ ability to enhance NAPL recovery. Four different nonionic surfactants (alkyl glucosides, linear/branched alcohol ethoxylates) were selected to establish structure-function relationships in some of these rocks. The synergistic mixing of alkyl glucosides with alkylphenol ethoxylates exhibited a compact geometrical packing at NAPL/brine interfaces and a complementary effect on IFT reduction and wettability alteration, recovering the largest amounts of NAPL in carbonate-bearing rocks compared to other surfactants. This mixture was then used to prepare a nanofluid composed of microemulsions with in-situ synthesized silica nanoparticles. The microscale NAPL displacements by the nanofluid in Arkose sandstone was examined using a micro-CT scanner integrated with a miniature core flooding system. The incremental NAPL removal with the nanofluid (34.3%) was higher than that of ME (20%) due to the emulsification of NAPL into smaller droplets. The latter could penetrate small capillary elements of the rock that were inaccessible to ME, causing stronger wettability alteration especially in microporous carbonate cements. The microscale dynamics of NAPL displacement was examined by injecting various amounts of nanofluid into Fond Du Lac carbonate. Tomography data revealed that NAPL droplets were emulsified within the first injected pore volume, mobilizing almost 50% of NAPL. The size of these droplets decreased from 9 to 3 μm with increasing amount of nanofluid delivered into the pores through advection and diffusion. Subsequent nanofluid injection further removed NAPL from the smaller pores by changing their wettability, leading to a reduced thickness of adsorbed NAPL layers, a narrower in-situ contact angle distribution, and an additional 16% of NAPL removal.

Multi-scale Experimental Investigation of the Effects of Nanofluids on Interfacial Properties and Their Implications for Enhanced Oil Recovery

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ISBN 13 : 9781687962522
Total Pages : 165 pages
Book Rating : 4.9/5 (625 download)

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Book Synopsis Multi-scale Experimental Investigation of the Effects of Nanofluids on Interfacial Properties and Their Implications for Enhanced Oil Recovery by : Wendi Kuang

Download or read book Multi-scale Experimental Investigation of the Effects of Nanofluids on Interfacial Properties and Their Implications for Enhanced Oil Recovery written by Wendi Kuang and published by . This book was released on 2019 with total page 165 pages. Available in PDF, EPUB and Kindle. Book excerpt: As major fractions of oil are left unexploited in reservoirs, novel enhanced oil recovery (EOR) methods are needed to recover larger portions of the fluid. Nanofluids have been reported to impact multi-phase flow behavior by various means. Nonetheless, the significance of some of the proposed effects is under debate, and the fundamental pore-scale mechanisms responsible for nanofluid-assisted EOR remain unexplained. In this work, we present the results of a multi-scale experimental study designed to develop a significantly improved understanding of the nanofluid-assisted EOR scheme. We first developed a stability assessment protocol to test the stability of, in total, eighteen nanofluids. Subsequently, the effects of stable nanofluids on interfacial properties were carefully characterized. Moreover, in order to probe the mechanisms of nanofluids at the pore scale, a miniature core-flooding apparatus, coupled with a high-resolution X-ray micro-CT scanner, was used to conduct experiments on rock samples. Oil production performance by spontaneous imbibition of both SiOx- and Al2O3-based nanofluids were tested in aged sandstone and dolomite samples. Furthermore, the effects of SiOx-based nanofluids on wettability were carefully evaluated by performing a pore-scale core-flooding experiment on oil-wet Berea sandstone samples at high-pressure and high-temperature conditions. This study reveals that wettability reversal is the primary factor responsible for the observed recovery enhancement when the selected nanofluids are introduced. While the effect of IFT reduction by nanofluids, which has been reported in some studies as a controlling factor, is less significant. However, we observed that the inclusion of surfactant in nanofluids could result in even higher oil recovery by triggering a synergistic effect through simultaneous wettability reversal and IFT reduction. By analyzing the fluid occupancy maps on a pore-by-pore basis, we observed that wettability reversal enabled the invasion of the displacing fluid into small pores by producing an imbibition flow process; while IFT reduction helped the displacing fluid to invade into pores that remained oil-wet. The combined effect of the former and the later phenomena produced the above-mentioned synergistic effect and generated superior oil recovery performance.

Pore-scale Characterization of Wettability and Displacement Mechanisms During Oil Mobilization Due to Waterflood-based Oil Recovery Schemes

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ISBN 13 : 9780438564718
Total Pages : 217 pages
Book Rating : 4.5/5 (647 download)

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Book Synopsis Pore-scale Characterization of Wettability and Displacement Mechanisms During Oil Mobilization Due to Waterflood-based Oil Recovery Schemes by : Mahdi Khishvand

Download or read book Pore-scale Characterization of Wettability and Displacement Mechanisms During Oil Mobilization Due to Waterflood-based Oil Recovery Schemes written by Mahdi Khishvand and published by . This book was released on 2018 with total page 217 pages. Available in PDF, EPUB and Kindle. Book excerpt: We present the results of an extensive pore-scale experimental study of trapping of oil in topologically disordered naturally-occurring pore spaces. A unique miniature core-flooding system is built and then integrated with a high-resolution micro-computed tomography (micro-CT) scanner to create a new experimental platform, which enables us to conduct flow experiments on a small rock specimen, nominally 5-mm-diameter, at conditions representative of subsurface reservoirs while the sample is being imaged. We develop robust experimental procedures and state-of-the-art image analysis techniques to characterize in-situ wettability and accurately map the spatial distribution of fluid phases at the pore level during various multiphase flow phenomena. This indeed has the possibility to transform our understanding of these important flow processes and allows us to have a much more effective way of designing enhanced oil recovery schemes deployed in a wide range of geological systems. Below, we list four key applications of this new approach, which are achieved under this study. These include: (1) In-situ characterization of wettability and pore-scale displacement mechanisms; (2) Micro-scale investigation of the effects of flow rate on nonwetting phase trapping; (3) Systematic examination of the impact of brine salinity on residual phase saturation; and (4) Experimental study of the remobilization of trapped oil ganglia associated with CO2 exsolution during carbonated water injection. Initially, we perform several two-phase experiments on Berea sandstone core samples and characterize contact angle hysteresis for various fluid pairs. Afterward, we carry out a three-phase experiment including a secondary gas injection followed by a waterflood and then an oilflood. We generate in-situ oil-water, gas-water, and gas-oil contact angle distributions during each stage of this flow experiment and compare them with the two-phase counterparts to develop new insights into relevant complex displacement mechanisms. The results indicate that, during gas injection, the majority of displacements involving oil and water are oil-to-water events. It is observed that, during the waterflood, both oil-to-gas and gas-to-oil displacement events take place. However, the relative frequency of the former is greater. For the oilflood, gas-water interfaces only slightly hinge in pore elements. Pore-scale fluid occupancy maps and the Bartell-Osterhoff constraint verify the above-mentioned findings. Secondly we conduct a pore-scale experimental study of residual trapping on consolidated water-wet sandstone and carbonate rock samples. We investigate how the changes in wetting phase flow rate impacts pore-scale trapping of the nonwetting phase as well as size and distribution of its disconnected globules. The results show that with increase in imbibition flow rate, the residual oil saturation reduces from 0.46 to 0.20 in Bemtheimer sandstone and from 0.46 to 0.28 in Gambier limestone. The reduction is believed to be caused by alteration of the order in which pore-scale displacements took place during imbibition. We use pore-scale displacement mechanisms, in-situ wettability characteristics, and pore size distribution information to explain the observed capillary desaturation trends. Furthermore, we explore that the volume of individual trapped oil globules decreases at higher brine flow rates. Moreover, it is found that the pore space in the limestone sample is considerably altered through matrix dissolution at extremely high brine flow rates. Imbibition in the altered pore space produces lower residual oil saturation (from 0.28 to 0.22) and significantly different distribution of trapped oil globules. Thirdly, a series of micro- and core-scale flow experiments are carried out on mixed-wet reservoir sandstone core samples at elevated temperature and pressure conditions to examine the impact of injection brine salinity on oil recovery and accentuate governing displacement mechanisms. Individual core samples are cut from a preserved reservoir whole core, saturated to establish initial reservoir fluid saturation conditions, and subsequently waterflooded with low- and high-salinity brines. In addition to the preserved experiments, several samples are cleaned, subjected to a wettability restoration process, and then used for waterflooding experiments. The results indicate approximate waterflood residual oil saturations (S[subscript]orw) of 0.25 and 0.39 for LSWF and HSWF, respectively. These observations highlight the remarkably superior performance of LSWF compared to that of HSWF. LSWF tests show a more prolonged oil recovery response than HSWF. The findings provide direct evidence that LSWF also causes a wettability alteration toward increasing water-wetness – due to limited release of mixed-wet clay particles and multi-component ion exchange, whereas contact angles measured during HSWF remain unchanged. It is observed that the reduction in oil-water contact angles lowers the threshold water pressure needed to displace oil from some medium-sized pore elements and enhances oil recovery during LSWF. Finally, we present the results of a micro-scale three-phase experimental study, using a spreading fluid system, of carbonated water injection and subsequent CO2 exsolution, as a consequence of pressure depletion, that lead to recovery of a significant fraction of trapped oil. Micro-CT visualization of pore occupancy show that the gradual increase in the pressure drop leads to exsolution of CO2, internal gas drive, mobilization of oil ganglia, and a notable reduction in waterflood residual oil saturation. When contacted by CO2, oil globules form thick spreading layers sandwiched between brine (in the corners) and gas (in the center of pores) and are displaced toward the outlet along with moving gas clusters. We observe significant re-connection of trapped oil globules due to oil layer formation during early stages of CWI. The oil layers stay stable until the very late stages of gas exsolution.

Experimental Evaluation of Nanoparticles Impact on Displacement Dynamics for Water-wet and Oil-wet Porous Media

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ISBN 13 :
Total Pages : 0 pages
Book Rating : 4.:/5 (95 download)

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Book Synopsis Experimental Evaluation of Nanoparticles Impact on Displacement Dynamics for Water-wet and Oil-wet Porous Media by : Abdullah Ali L Alghamdi

Download or read book Experimental Evaluation of Nanoparticles Impact on Displacement Dynamics for Water-wet and Oil-wet Porous Media written by Abdullah Ali L Alghamdi and published by . This book was released on 2015 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: The potential of utilizing nanoparticles for production enhancement during oil-water displacement can play a significant role to achieve efficient and sustainable production of resources as they have shown great promise in stabilizing emulsion inside porous media. Furthermore, the displacement of brine solution containing nanoparticles by another non-wetting phase such as n-octane under water-wet condition has been shown to produce the signs of nanoparticle-stabilized emulsion. Because it is hypothesized that emulsion effects are caused by pore scale events that shear the fluids, this research aims to evaluate the impact of nanoparticles on different displacement scenarios (primary imbibition, primary drainage, secondary imbibition, and secondary drainage) and address the effect of wettability (oil-wet vs. water-wet), displacement types (different pore scale processes), and viscous stability (lower viscosity n-octane vs. higher viscosity tetradecane) on the generation of nanoparticle-stabilized emulsion in situ during immiscible displacement. Studying the impact of these changes is of primary importance since they contribute to changing pore scale events, fluids positioning and distribution, and displacement stability. Nanoparticle-stabilized emulsion has been associated with some indirect observable signs which include i) a rapid pressure drop increase exceeding the viscosity ratio between the brine and brine-nanoparticle dispersion, ii) a later breakthrough, iii) a reduction in resident fluid residual saturation, and iv) a reduction of the invading phase endpoint relative permeability. Therefore, the impact of nanoparticles on the displacement was evaluated by measuring pressure drop data and effluent fluid histories. Those data were used to indicate the signs of nanoparticle-stabilized emulsion generation by interpreting pressure drop trends, water saturation histories, pressure drop ratio profile, residual fluid saturation, and endpoint relative permeability of the invading phase. Furthermore, the study attempts to examine the hypothesis that the displacement of a wetting hydrocarbon phase containing hydrophobic nanoparticles by another non-wetting aqueous phase will also generate nanoparticle-stabilized emulsion symptoms. This research reveals that compared to the control case (no nanoparticles), nanoparticles have the greatest effect on drainage type displacement (hydrocarbon invasion) with pressure drop reaching up to 500 % or even greater compared to the initial pressure drop observed at the start of the displacement. It also shows that those particles have little effect on imbibition displacement (aqueous phase invasion). This was found to be true for both oil-wet and water-wet despite the fact that fluids are configured differently at the pore-scale level. As for a more viscous hydrocarbon phase (tetradecane), the observed effects are generally lessened. As for secondary drainage displacement, initial trapping and the distribution of the hydrocarbon phase has also reduced the severity of the emulsion generation process. Based on the previous findings, an attempt to test the hypothesis of displacing hydrophobic nanoparticle dispersion by an aqueous brine solution under oil-wet condition was inconclusive due to the difficulty of maintaining stable hydrocarbon-nanoparticle dispersion. The displacement profile for all imbibition cases showed no significant differences between nanoparticle case and control case. Yet, we observe that nanoparticles have caused a reduction in the residual hydrocarbon saturation. This reduction was slightly greater for water-wet core compared to oil-wet. For these results I conclude that Haines jump and Roof snap-off may be one of the primary processes responsible to generate nanoparticle-stabilized emulsion during drainage displacement. However, observing emulsion symptoms during secondary drainage in oil-wet cores suggest either a) exact configuration is not important or b) possible alteration in the rock wettability by nanoparticles to produce the same configuration. The viscosity results suggest that nanoparticle effects have largely altered the conformance of the displacement. The presence of ethylene glycol and/or other coating chemicals used to maintain stability of nanoparticle dispersion may have caused the reduction of hydrocarbon phase residual saturation during all imbibition type displacement.

MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSORPTION FOR IMPROVED OIL RECOVERY.

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ISBN 13 :
Total Pages : pages
Book Rating : 4.:/5 (685 download)

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Book Synopsis MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSORPTION FOR IMPROVED OIL RECOVERY. by :

Download or read book MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSORPTION FOR IMPROVED OIL RECOVERY. written by and published by . This book was released on 2005 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt:

Nanofluid Flow in Porous Media

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Publisher : BoD – Books on Demand
ISBN 13 : 1789238374
Total Pages : 246 pages
Book Rating : 4.7/5 (892 download)

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Book Synopsis Nanofluid Flow in Porous Media by : Mohsen Sheikholeslami Kandelousi

Download or read book Nanofluid Flow in Porous Media written by Mohsen Sheikholeslami Kandelousi and published by BoD – Books on Demand. This book was released on 2020-08-19 with total page 246 pages. Available in PDF, EPUB and Kindle. Book excerpt: Studies of fluid flow and heat transfer in a porous medium have been the subject of continuous interest for the past several decades because of the wide range of applications, such as geothermal systems, drying technologies, production of thermal isolators, control of pollutant spread in groundwater, insulation of buildings, solar power collectors, design of nuclear reactors, and compact heat exchangers, etc. There are several models for simulating porous media such as the Darcy model, Non-Darcy model, and non-equilibrium model. In porous media applications, such as the environmental impact of buried nuclear heat-generating waste, chemical reactors, thermal energy transport/storage systems, the cooling of electronic devices, etc., a temperature discrepancy between the solid matrix and the saturating fluid has been observed and recognized.

Multiphase Flow in Porous Media: the Impact of Capillarity and Wettability from Field-scale to Pore-scale

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ISBN 13 :
Total Pages : 104 pages
Book Rating : 4.:/5 (986 download)

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Book Synopsis Multiphase Flow in Porous Media: the Impact of Capillarity and Wettability from Field-scale to Pore-scale by : Benzhong Zhao

Download or read book Multiphase Flow in Porous Media: the Impact of Capillarity and Wettability from Field-scale to Pore-scale written by Benzhong Zhao and published by . This book was released on 2017 with total page 104 pages. Available in PDF, EPUB and Kindle. Book excerpt: Multiphase flow in the context of this Thesis refers to the simultaneous flow of immiscible fluids. It differs significantly from single-phase flow due to the existence of fluid-fluid interfaces, which are subject to capillary forces. Multiphase flow in porous media is important in many natural and industrial processes, including geologic carbon dioxide (CO2) sequestration, enhanced oil recovery, and water infiltration into soil. Despite its importance, much of our current description of multiphase flow in porous media is based on semi-empirical extensions of single-phase flow theories, which miss key physical mechanisms that are unique to multiphase systems. One challenging aspect of solving this problem is visualization-flow typically occurs inside opaque media and hence eludes direct observation. Another challenging aspect of multiphase flow in porous media is that it encompasses a wide spectrum of length scales-while capillary force is active at the pore-scale (on the order of microns), it can have a significant impact at the field-scale (on the order of kilometers). In this Thesis, we employ novel laboratory experiments and mathematical modeling to study multiphase flow in porous media across scales. The field-scale portion of this Thesis focuses on gravity-driven flows in the subsurface, with an emphasis on application to geological CO2 storage. We find that capillary forces can slow and stop the migration of a CO2 plume. The meso-scale portion of this Thesis demonstrates the powerful control of wettability on multiphase flow in porous media, which is manifested in the markedly different invasion protocols that emerge when one fluid displaces another in a patterned microfluidic cell. The pore-scale portion of this Thesis focuses on the impact of wettability on fluid-fluid displacement inside a capillary tube. We show that the contact line movement is strongly affected by wettability, even in regimes where viscous forces dominate capillary forces.

MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSOPTION FOR IMPROVED OIL RECOVERY.

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ISBN 13 :
Total Pages : pages
Book Rating : 4.:/5 (684 download)

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Book Synopsis MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSOPTION FOR IMPROVED OIL RECOVERY. by :

Download or read book MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSOPTION FOR IMPROVED OIL RECOVERY. written by and published by . This book was released on 2004 with total page pages. Available in PDF, EPUB and Kindle. Book excerpt: The aim of the project is to delineate the role of mineralogy of reservoir rocks in determining interactions between reservoir minerals and externally added reagents (surfactants/polymers) and its effect on the solid-liquid and liquid-liquid interfacial properties such as adsorption, wettability and interfacial tension in systems relevant to reservoir conditions. Previous studies have suggested that significant surfactant loss by precipitation or adsorption on reservoir minerals can cause chemical schemes to be less than satisfactory for enhanced oil recovery. Both macroscopic adsorption, wettability and microscopic orientation and conformation studies for various surfactant/polymer mixtures/reservoir rocks systems will be conducted to explore the cause of chemical loss by means of precipitation or adsorption, and the effect of rock mineralogy on the chemical loss. During this reporting period, the minerals used have been characterized, for particle size distribution and surface area. Also a series of novel cationic Gemini surfactants: butane-1,4-bis(quaternary ammonium chloride), has been synthesized. The solution and adsorption behavior of individual surfactants, the highly surface-active Gemini surfactant C[sub 12]-C[sub 4]-C[sub 12], the sugar-based nonionic surfactant n-dodecyl-[beta]-D-maltoside (DM) and their mixture has been studied. DM alone shows low adsorption on silica because of the lack of any electrostatic attraction between the surfactant and the silica particle. On the other hand, the cationic Gemini adsorbs markedly on the oppositely charged silica surface. Marked synergism has been observed in the case of DM/C[sub 12]-C[sub 4]-C[sub 12] mixture adsorption on silica. Adsorption of DM from the mixtures increases dramatically in both the rising part and the plateau regions. Adsorption of the cationic Gemini C[sub 12]-C[sub 4]-C[sub 12] from the mixture on the other hand increases in the rising part, but decreases in the plateau regions due to the competition for adsorption sites from DM. Desired mineral surface property, that may be obtained using the proper mixtures of DM and Gemini under optimal conditions, can help to control the mineral wettability to facilitate oil liberation in improved oil recovery processes.

Wettability Effects on Flow Through Porous Media

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ISBN 13 :
Total Pages : 416 pages
Book Rating : 4.:/5 (319 download)

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Book Synopsis Wettability Effects on Flow Through Porous Media by : Sandeep Dhawan

Download or read book Wettability Effects on Flow Through Porous Media written by Sandeep Dhawan and published by . This book was released on 1994 with total page 416 pages. Available in PDF, EPUB and Kindle. Book excerpt:

The Effect of Wettability and Pore Geometry on Three Phase Fluid Displacement in Porous Media [microform]

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Publisher : National Library of Canada
ISBN 13 :
Total Pages : 111 pages
Book Rating : 4.:/5 (76 download)

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Book Synopsis The Effect of Wettability and Pore Geometry on Three Phase Fluid Displacement in Porous Media [microform] by : V. William (Veehorne William) Tang Kong

Download or read book The Effect of Wettability and Pore Geometry on Three Phase Fluid Displacement in Porous Media [microform] written by V. William (Veehorne William) Tang Kong and published by National Library of Canada. This book was released on 1988 with total page 111 pages. Available in PDF, EPUB and Kindle. Book excerpt:

MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSORPTION FOR IMPROVED OIL RECOVERY.

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ISBN 13 :
Total Pages : 32 pages
Book Rating : 4.:/5 (316 download)

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Book Synopsis MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSORPTION FOR IMPROVED OIL RECOVERY. by : P. Somasundaran

Download or read book MINERAL-SURFACTANT INTERACTIONS FOR MINIMUM REAGENTS PRECIPITATION AND ADSORPTION FOR IMPROVED OIL RECOVERY. written by P. Somasundaran and published by . This book was released on 2004 with total page 32 pages. Available in PDF, EPUB and Kindle. Book excerpt: Significant surfactant loss by adsorption or precipitation on reservoir minerals can cause chemical flooding processes to be less than satisfactory for enhanced oil recovery. This project is aimed towards an understanding of the role of reservoir minerals and their dissolved species in chemical loss by precipitation or adsorption of surfactants/polymers in enhanced oil recovery. Emphasis will be on the type and nature of different minerals in the oil reservoirs. Macroscopic adsorption, precipitation, wettability and nanoscopic orientation/conformation studies for aggregates of various surfactant/polymer mixtures on reservoir rocks systems is planned for exploring the cause of chemical loss by means of precipitation or adsorption, and the effect of rock mineralogy on the chemical loss. During this reporting period, the minerals proposed in this study: sandstone, limestone, gypsum, kaolinite and pyrite, have been characterized to obtain their particle size distribution and surface area, which will be used in the analysis of adsorption and wettability data. The effect of surfactant mixing ratio on the adsorption of mixture of C{sub 12}-C{sub 4}-C{sub 12} Gemini surfactant (synthesized during last period) and sugar-based nonionic surfactant n-dodecyl-{beta}-D-maltoside (DM) has been studied. It was discovered that even trace amounts of Gemini in the mixture is sufficient to force significant adsorption of DM. DM adsorption on silica increased from relatively negligible levels to very high levels. It is clear form analysis of the results that desired adsorption of either surfactant component in the mixtures can be obtained by controlling the mixing ratio, the total mixture concentration, pH etc. Along with these adsorption studies, changes in mineral wettability due to the adsorption of Gemini/DM mixtures were determined under relevant conditions to identify the nano-structure of the adsorbed layers. With increasing total surfactant adsorption, the silica mineral undergoes a wettability change from hydrophilic surface to hydrophobic and then revert to hydrophilic surface. The hydrophilic-hydrophobic transition point is determined also by surfactant mixing ratio. The corresponding solution behavior of mixed systems has been studied, and interaction parameters between the component surfactants have been determined, in comparison with the surfactant interactions at solid/liquid and liquid/liquid interfaces. Mineral surface modification due to the adsorption of mixed surfactants of DM and Gemini under optimal conditions, can be employed to control the mineral wettability to facilitate oil liberation in improved oil recovery processes.

Pore Space Deformation and Its Implications for Multiphase Flow Through Porous Media Under Various Wettability Conditions

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ISBN 13 :
Total Pages : 0 pages
Book Rating : 4.8/5 (417 download)

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Book Synopsis Pore Space Deformation and Its Implications for Multiphase Flow Through Porous Media Under Various Wettability Conditions by : Rui Wang

Download or read book Pore Space Deformation and Its Implications for Multiphase Flow Through Porous Media Under Various Wettability Conditions written by Rui Wang and published by . This book was released on 2022 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Pore space deformation significantly affects multiphase flow behavior in porous media. It alters the distribution of fluids at the pore scale which in turn leads to changes in the effective permeability, relative permeability, capillary pressure, etc. However, due to the lack of fundamental studies on the mechanisms correlating the pore-level fluid displacements with the pore space deformation, no compelling conclusions have been reached to account for the observed effects. To explore this correlation, a series of carefully characterized unsteady- and steady-state two-phase core-flooding experiments were performed on miniature sandpack samples under varying stress conditions while the pore space was being imaged using high-resolution x-ray microtomography techniques to acquire three-dimensional pore fluid configuration maps. In these studies, the deformation of the sandpack samples was characterized at both macro and micro scales. The impact of deformation on the frequency of various pore-scale fluid displacement mechanisms as well as fluid saturations and volumes during different flow processes (drainage and imbibition) were also investigated. Changes in the multiphase flow behavior, such as fluid velocity and pressure, were evaluated through direct simulations, which used a finite volume method to solve Navier-Stoke equations. Moreover, the variations in the in-situ capillary pressure caused by the pore space deformation were explored through interfacial curvature analysis. The relationship between relative permeabilities and effective stress was probed. Finally, in connection to the geological storage of carbon dioxide in deep saline aquifers, the impact of pore space deformation on residual trapping and dissolution of supercritical CO2 in brine saturated sandpacks was carefully examined through micro-scale flow experiments conducted under varying stress conditions. It was observed that in a water-wet porous medium, unsteady-state drainage can be both strengthened due to the higher fluid velocity and weakened by the increase in the threshold capillary pressure after the pore space contraction. By contrast, unsteady imbibition was affected solely by variations in the threshold capillary pressure and, consequently, was facilitated as the pore sizes reduced. During the steady-state core-flooding tests, additional drainage and imbibition displacements were triggered by the pore space expansion and contraction, respectively. Furthermore, it was found that wettability was one of the key properties that governed the impact of pore space deformation on the multiphase flow behavior in porous media. The wetting phase hydraulic conductivity was more sensitive to the pore space deformation than that of the non-wetting phase, because of their topologically different distributions in the pore space. Consequently, the relative permeability of the wetting phase decreased with the increase in the effective stress, while that of the non-wetting phase increased. However, this behavior changed as the wettability of the porous medium was altered to a weakly oil-wet state through a dynamic aging process. These studies provided novel insights into the fluid flow behavior in unconsolidated porous media under varying stress conditions, which are of ever-increasing importance to many subsurface applications, including hydrocarbon recovery, water management, CO2 sequestration, and hydrogen storage.

The Influence of Interfacial Phenomena on Fluid Physics in Multiscale Porous Media

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ISBN 13 :
Total Pages : 193 pages
Book Rating : 4.4/5 (387 download)

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Book Synopsis The Influence of Interfacial Phenomena on Fluid Physics in Multiscale Porous Media by : Erik Robert Smith

Download or read book The Influence of Interfacial Phenomena on Fluid Physics in Multiscale Porous Media written by Erik Robert Smith and published by . This book was released on 2022 with total page 193 pages. Available in PDF, EPUB and Kindle. Book excerpt: With growing energy demands and increased concern for global warming, the oil and gas industry has shifted focus to providing alternatives to standard conventional oil production. Petroleum companies are increasing energy production through secondary and tertiary techniques and the exploration of unconventional formations. This increased production is mirrored by environmental remediation techniques such as carbon dioxide geosequestration. Research has shifted to align with industry direction to resolve the challenges presented in this transition. The existing challenges stem from the increased pore-scale variability and complex pore boundary behavior. This work focuses on understanding interfacial phenomena under confinement. The first portion of this dissertation reports insights into how a fluid alters surfaces through chemical and physical modifications. The second portion describes a unique approach to studying a fluid’s density that is influenced by the multiscale pore architecture in porous media. The use of a surrogate material, natural or synthetic, minimizes the unknowns associated with mineralogy and pore size variability and deepens our understanding of the combined effects of surface energy and constraint geometries. These results will highlight the importance of interfacial interactions in porous media. A key finding of the first portion of this dissertation proves the time-sensitivity of induced and natural wettability alteration. In the second portion, we present a unique multiscale approach to determining the scaling of a multiphysics phenomenon known as capillary condensation. The capillary condensation study also improves the standard pore-size perspective to a coupled surface energy and pore-size approach.

Wettability in Porous Media - From Macroscopic Measurements to Pore-scale Characterization

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ISBN 13 :
Total Pages : 0 pages
Book Rating : 4.:/5 (122 download)

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Book Synopsis Wettability in Porous Media - From Macroscopic Measurements to Pore-scale Characterization by : Prisca Andriamananjaona

Download or read book Wettability in Porous Media - From Macroscopic Measurements to Pore-scale Characterization written by Prisca Andriamananjaona and published by . This book was released on 2020 with total page 0 pages. Available in PDF, EPUB and Kindle. Book excerpt: Wettability refers to the relative affinity of a solid material for one fluid in the presence of another fluid. This property is usually inferred from the measurement of the contact angle formed at the triple-point, i.e. the point where the three phases meet. Wettability is a crucial parameter to be considered when dealing with multiphase flows in confined porous media as it dramatically impacts the fluids distribution. This property is therefore of major concern in the petroleum industry as it has, among others, an influence on the relative permeability, on the efficiency of one recovery process over another, and ultimately on the amount of recoverable oil. In an oil reservoir subjected to recovery by waterflooding for example, the amount of produced oil will highly differ if the rock is water wet, or oil wet. Despite the well-established correlation between wettability and recovery efficiency, its distinct characterization and impact at the pore-level remains poorly understood. Reservoir rocks are porous media, i.e. composed of a solid matrix and a connected pore-space. The fluids are located in micrometer-sized pores, rendering direct observation challenging. To overcome that difficulty, empirical measurements were devised to evaluate rocks wettability. The most widespread tests in the petrophysical community are based on the amount of recovered fluids after successive flows. The present work focuses on Amott tests performed on rock/water/oil systems. The wettability state is given by three indices obtained through recovery measurements after successive spontaneous and forced flow. The extreme wettability state presents no ambiguity whereas the intermediate states can be trickier to interpret. Different combinations of indices can yield the same global index, while referring to very different pore-scale phenomena. The advent of powerful imaging methods now allows observing the phenomena occurring in the pore-space. The objective of the current study aims at conciliating the classic macroscopic determination of the wettability state with its manifestation at the pore-scale. To do so, we use laboratory microcomputed tomography (μCT). This technique allows to access to the pore-scale in a non-destructive fashion. It is similar to the imaging methods used in medical applications, but with a resolution that allows to access to the micron scale. In this work, we therefore conduct μCT acquisitions after each flow step of the Amott test. However, as the Amott test is a volume-based measurement, it requires centimeter-sized sample to limit he measurement uncertainty, whereas the μCT technique requires millimeter-sized samples to be able to reliably vizualize the pore-space. To resolve this conflict, we perform our experiments on Bentheimer sandstone as the biggest portion of its pore space is observable by means of μCT, while still being a representative rock for conventional oil reservoirs. Furthermore, we choose to perform the Amott tests on at least two differents sample sizes: the classical plug (centimeter sized), and one or two mini-plugs, suitable for imaging. To be as representative as possible, all samples are subjected to the same flow conditions, at the same time. The first part of this work therefore focuses on the adaptation of the conventional experimental procedure towards small rock samples, and the validation of the change-of-scales: we especially highlight some end effects after spontaneous flow that impact the saturation state differently, depending on the sample size. The second part of the work focuses on the comparison between the wettability state given by the Amott test, and the corresponding analyses at the pore-scale. We confront three distinct wettability states covering the range from water-wet, over intermediate wet to oil wet. The pore-scale analyses corroborate the Amott test results, and help to advance the understanding of pore-scale phenomena.

Pore-scale Experimental Investigations of Immiscible Displacements in Capillary Tubes and Porous Micromodels

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ISBN 13 : 9780438429505
Total Pages : 124 pages
Book Rating : 4.4/5 (295 download)

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Book Synopsis Pore-scale Experimental Investigations of Immiscible Displacements in Capillary Tubes and Porous Micromodels by : Mohammad Heshmati

Download or read book Pore-scale Experimental Investigations of Immiscible Displacements in Capillary Tubes and Porous Micromodels written by Mohammad Heshmati and published by . This book was released on 2017 with total page 124 pages. Available in PDF, EPUB and Kindle. Book excerpt: Owing to the complicated nature of a porous medium, study of dynamics of fluid flow in such structures is not straightforward. Therefore, researchers have been using simplified one-dimensional (1D) and two-dimensional (2D) porous media models like capillary tubes, micro-models and micro-fluidic devices to perform such studies. We utilized both of these categories to investigate different parameters affecting the flow of fluids in a porous medium. In 1D, capillary tubes of different cross-sectional shapes and several wetting fluids are used to investigate the evolution of dynamic contact angle with the meniscus velocity. The meniscus rise vs. time curves produced by Washburn's equation are improved by implementing our experimentally measured dynamic contact angle values into the Washburn's original equation. A general empirical correlation is presented for variation of normalized rise with dynamic contact angle as well. In the second category, a novel two-phase, two-field-of-view micro-Particle-Image-Velocimetry system is developed. It allows simultaneous study of flow fields at the pore- and micromodel-scales and provides a deeper insight into the distribution of fluids. The effect of change of flow rate on shear stress at the interface of invading and defending fluids in a designed pore-doublet configuration made of Polydimethylsiloxane (PDMS) is studied. The impact of local perturbations of velocity fields on displacement of non-wetting phase and the residual trapping is also discussed. We show that these effects produce extensively different distributions of the trapped non-wetting phase globules. A modified 2D X-ray micro-computed tomography image of Bentheimer sandstone is replicated on PDMS. Single-phase velocity measurements in these models afford valuable insights into the complicated flow patterns through a porous medium; whereas in two-phase flow tests, in addition to resolving the velocity fields in both fluids, effects of changes in invading wetting phase flow rate and viscosity on pore fluid configuration and residual trapping is investigated as well. Not only these results provide a valuable understanding of the complexities of flow through porous systems, but also they can be used to validate the numerical models of fluid flow through porous systems.

Wettability and Interfacial Phenomena - Implications for Material Processing

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ISBN 13 : 9781838805395
Total Pages : 158 pages
Book Rating : 4.8/5 (53 download)

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Book Synopsis Wettability and Interfacial Phenomena - Implications for Material Processing by : Rita Khanna

Download or read book Wettability and Interfacial Phenomena - Implications for Material Processing written by Rita Khanna and published by . This book was released on 2019 with total page 158 pages. Available in PDF, EPUB and Kindle. Book excerpt: Wettability at the solid/liquid interface, its dynamics, tunability, the influence of operating parameters, surface and interfacial phenomena play an increasingly significant role in a wide variety of applications, for example, material processing, nanotechnology, oil recovery, oil spills, chemical leaching, water management, and disease transmission. Although a mature field, it is experiencing dramatic developments on several fronts with emerging applications in new fields. This book presents a collection of eight chapters on nanoscale wetting phenomena, oil extraction from reservoir rocks, the role of coatings, particle morphology, surface roughness and viscosity in metal processing, and practical applications of superhydrophobic behaviour in cell culturing, isolation, anti-icing, anti-reflective and anti-corrosion coatings in the transportation and optical devices fields.

Foams and Emulsions

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Publisher : Springer Science & Business Media
ISBN 13 : 0792356160
Total Pages : 614 pages
Book Rating : 4.7/5 (923 download)

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Book Synopsis Foams and Emulsions by : J.F. Sadoc

Download or read book Foams and Emulsions written by J.F. Sadoc and published by Springer Science & Business Media. This book was released on 1999-03-31 with total page 614 pages. Available in PDF, EPUB and Kindle. Book excerpt: A general and introductory survey of foams, emulsions and cellular materials. Foams and emulsions are illustrations of some fundamental concepts in statistical thermodynamics, rheology, elasticity and the physics and chemistry of divided media and interfaces. They also give rise to some of the most beautiful geometrical shapes and tilings, ordered or disordered. The chapters are grouped into sections having fairly loose boundaries. Each chapter is intelligible alone, but cross referencing means that the few concepts that may not be familiar to the reader can be found in other chapters in the book. Audience: Research students, researchers and teachers in physics, physical chemistry, materials science, mechanical engineering and geometry.