Suminar et al., 2021 - Google Patents
Detecting Phase-Inversion Region of Surfactant-Stabilized Oil/Water Emulsions Using Differential Dielectric SensorsSuminar et al., 2021
- Document ID
- 7620269365814135334
- Author
- Suminar K
- Gavrielatos I
- Dabirian R
- Mohan R
- Shoham O
- Publication year
- Publication venue
- SPE Production & Operations
External Links
Snippet
An experimental and theoretical investigation of surfactant-stabilized oil/water emulsion characteristics was carried out under water sweep (WS) and oil sweep (OS) conditions. Both hydrophilic and hydrophobic surfactants were used, with concentrations less than and more …
- 239000000839 emulsion 0 title abstract description 89
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Khan et al. | Influence of alkali-surfactant-polymer flooding on the coalescence and sedimentation of oil/water emulsion in gravity separation | |
| Piroozian et al. | A mechanistic understanding of the water-in-heavy oil emulsion viscosity variation: Effect of asphaltene and wax migration | |
| Akhfash et al. | Gas hydrate plug formation in partially-dispersed water–oil systems | |
| Wang et al. | Investigation on heavy crude-water two phase flow and related flow characteristics | |
| Gavrielatos et al. | Effect of intermediate wettability nanoparticles on oil-water emulsion stability | |
| Bulgarelli et al. | Relative viscosity model for oil/water stable emulsion flow within electrical submersible pumps | |
| dos Santos et al. | Laminar pipeline flow of heavy oil–in–water emulsions produced by continuous in-line emulsification | |
| Piela et al. | Experimental investigation of phase inversion in an oil–water flow through a horizontal pipe loop | |
| US9581581B2 (en) | Methods of determining crude oil stability | |
| Wei et al. | Prediction of the apparent viscosity of non-Newtonian water-in-crude oil emulsions | |
| Rodionova et al. | Preparation and characterization of reference fluid mimicking behavior of North Sea heavy crude oil | |
| Abbasi et al. | Stability of acid in crude oil emulsion based on interaction energies during well stimulation using HCl acid | |
| Gonzalez et al. | Pipe flow experiments of unstable oil-water dispersions with three different oil viscosities: Flow pattern, pressure drop and droplet size measurements | |
| Velayati et al. | Formulating a model emulsion replicating SAGD in-situ emulsions | |
| Hu et al. | Phase Inversion and Associated Phenomena in Oil‐Water Vertical Pipeline Flow | |
| Majid | An investigation on the viscosity and transportability of methane hydrate slurries using a high pressure rheometer and flowloop | |
| Suminar et al. | Detecting Phase-Inversion Region of Surfactant-Stabilized Oil/Water Emulsions Using Differential Dielectric Sensors | |
| Silva Filho et al. | Impact of crude oil emulsion on pipeline corrosion | |
| Cassar et al. | Effect of Enhanced-Oil-Recovery Chemicals on Oil/Water-Separation Processes, from Laboratory Scale to Flow-Loop Scale | |
| Shmueli et al. | Oil/Water Pipe-flow dispersions: From traditional flow loops to real industrial-transport conditions | |
| Corona et al. | Study of the stability of model emulsions mimicking petroleum with different types of non-ionic surfactants | |
| Hapanowicz | Phase inversion in liquid–liquid pipe flow | |
| Silva et al. | Evaluation of the impact of crude oil emulsion on pipeline corrosion | |
| Vera et al. | Oil characteristics, water/oil wetting and flow influence on the metal loss corrosion. Part 1: Effect of oil and flow on CO2/H2S corrosion | |
| Alanazi et al. | Effect of Water Cut and Temperature on the Stability of Emulsifier-Free Oil-Water Dispersion in Batch Separators at Various Stirrer Speeds |