Your search keyword '"gas blocking"' showing total 4 results

1. Study on the unsteady flow characteristics of gas unblocking in multiphase pumps

Author

Wang, Meiling, Huang, Zhiqiang, Qian, Weiji, and Ma, Yachao

Published

2025

2. The Mechanism of Air Blocking in the Impeller of Multiphase Pump.

Author

Zhang, Sicong, Han, Wei, Xue, Tongqing, Qiang, Pan, Li, Rennian, and Mi, Jiandong

Subjects

*SHEAR flow, *PHASE separation, *GAS fields, *OIL fields, *GAS flow, *FLOW separation

Abstract

The exploitation and transportation of deep-sea and remote oil and gas fields have risen to become important components of national energy strategies. The gas–liquid separation and gas blocking caused by the large density difference between the gas and liquid phases are the primary influencing factors for the safe and reliable operation of gas–liquid mixed transportation pump systems. This paper takes the independently designed single-stage helical axial-flow mixed transportation pump compression unit as the research object. Through numerical simulation, the internal flow of the mixed transportation pump is numerically calculated to study the aggregation and conglomeration of small gas clusters in the flow passage hub caused by gas–liquid phase separation, influenced by the shear flow of phase separation, forming axial vortices at the outlet where gas clusters gather in the flow passage. The work performed by the impeller on the gas clusters is insufficient to overcome the adverse pressure gradient formed at the outlet of the flow passage due to the gathering of the liquid phase in adjacent flow passages, resulting in the phenomenon of gas blocking, with vortex gas clusters lingering near the hub wall of the flow passage. [ABSTRACT FROM AUTHOR]

Published

2024

3. Properties of N2- and CO2-foams as a function of pressure.

Author

Aarra, Morten Gunnar, Skauge, Arne, Solbakken, Jonas, and Ormehaug, Per Arne

Subjects

*NITROGEN, *CARBON dioxide, *PRESSURE, *ENHANCED oil recovery, *GAS injection, *RESERVOIRS, *COMPARATIVE studies, *SEAWATER

Abstract

Abstract: In enhanced oil recovery (EOR) operations foam has been applied to improve sweep during gas injection or for gas shut-off. Field experiences for North Sea reservoirs involve foams using hydrocarbon gas for conformance control and gas blocking in high pressure and high temperature fields. Generally foam field applications have utilized CO2 and N2 in addition to hydrocarbon gas. As reservoir conditions vary significantly it is important to understand foam properties on a broad experimental basis. The large changes in physical properties with temperature and pressure may affect CO2-foam properties and these are discussed by varying pressure from 30 to 280bar in an outcrop Berea sandstone core material at 50°C. The CO2-foam properties were compared to N2-foams. Foam was generated by co-injection of surfactant solution (AOS) and N2 or CO2 at 80% foam quality (fraction gas) at a total injection rate of 40ml/h. Strong N2-foams were generated both at 30 and 280bar. In general, N2-foams were stronger than CO2-foams. Comparing CO2-foams at different pressures showed that CO2-foams at 30bar were strong (MRF ~50–75) whereas supercritical CO2-foams gave MRFs in the range of 3–6. The visual foam structure observations from a sight glass at the core outlet showed denser N2-foams compared to CO2-foams. Injecting seawater after N2-foam showed that relative seawater permeability was low and remained low (<0.1) after injecting more than 10 pore volumes of seawater. Indeed, similar and positive results were obtained both for experiments run at 30 and 280bar. Mass transfer was found to be very important for CO2-foam stability. Results from two CO2-foam flooding experiments with equilibrated fluids at 30bar and 50°C showed improved foam strength, even though the largest improvement was observed for foams ability to block seawater. The water relative permeability was strongly reduced in the presence of foam, thus providing the reservoir engineer with another tool for water blocking. [Copyright &y& Elsevier]

Published

2014

4. Enhancing the productivity of volatile oil reservoirs using fluorinated chemical treatments

Author

Torres López, David Enrique

Subjects

Volatile oil, Fluorinated surfactants, Gas blocking, Wettability alteration

Abstract

Many producing volatile oil reservoirs experience a significant decrease in well deliverability when the bottom-hole pressure of the well falls below the bubble point pressure. This is due to the liberation of a gas phase which resides in the pore space and blocks the flow of the oil phase. This situation is known as "gas blocking". This occurs because the presence of two or three immiscible phases (gas, oil and water) results in a reduction of the oil saturation and a decrease in the oil relative permeability. The main objective of this research was to develop an effective and durable chemical treatment method to improve and/or restore the productivity of volatile oil wells undergoing "gas blocking". The treatment method is based on the use of fluorinated surfactants in tailored solvents to increase the oil relative permeability by changing the wettability of the rock’s surface. High-temperature high-pressure (HTHP) core flood experiments were used to evaluate the uses of fluorinated surfactants under reservoir conditions. Analytical tools such as X-ray photoelectron spectroscopy (XPS), high-performance liquid chromatography (HPLC) and computerized axial tomography (CT Scan) were also used to interpret the experimental results. High-pressure high-temperature (HPHT) coreflood tests showed that the treatments improved the oil and gas relative permeability in both sandstone and limestone cores. This was observed for synthetic volatile oil mixtures with gas-oil ratios (GOR) in the range of 4000 to 13,000 scf/STB at low capillary numbers (Nc) on the order of 1x10-5 to 1x10-6 and for PVT ratios greater than 0.5. The fluorinated chemical treatments were effective in the presence of connate water over the temperature range of 155°F to 275°F. Wettability alteration was measured using contact angle and imbibition rate tests. Results from analytical tools showed that fluorinated surfactants were uniformly adsorbed along the core and the surfactant desorption after treatment was low (10 ppm or less). The gas saturation decreased following treatment and both the oil and gas relative permeability increased. Numerical simulations using the measured relative permeability data were used to estimate the gain in productivity for treated wells. The proposed fluorinated chemical treatments could be used as a preventive treatment or for a damaged well that has already been producing below the bubble point to increase oil production rates and recoverable reserves.

Published

2011