Your search keyword '"WATER-gas"' showing total 3 results

1. Simulation study of water and gas injection process into the Azadegan reservoir for enhanced oil recovery.

Author

Farahbod, Farshad

Subjects

ENHANCED oil recovery, WATER-gas, GAS injection, OIL fields, PETROLEUM reservoirs, GAS reservoirs

Abstract

It is necessary to improve oil production from reservoirs. Various methods have been proposed to increase oil extraction from reservoir. Each method has specific challenges. In this research, the effect of water and gas injection in to Azadegan reservoir has been analyzed. Azadegan oil field is located south of Iran. In this study, water, immiscible gas and water alternating gas injected to reservoir and its effect on enhanced oil recovery have been investigated. Finally, a comparison between results of methods is provided. Results show that effective method for enhanced oil recovery is immiscible gas injection with 46% oil production efficiency and water alternating gas injection with 36% oil production efficiency. This study shows that oil production efficiency can be increased if duration of gas injection is increased. This study shows, increasing viscosity of water in water alternating gas scenario did not improve the production of Azadegan reservoir. [ABSTRACT FROM AUTHOR]

Published

2024

2. Significant production improvement using optimization of completion and artificial lift: case studies from South-West Iran.

Author

Ashena, Rahman, Bataee, Mahmood, Jafarpour, Hamed, Abbasi, Hamid, Zolotukhin, Anatoly, and Mirhashemi, Mohammad

Subjects

OIL well gas lift, GAS injection, NODAL analysis, WATER-gas, CHRISTMAS trees, GAS wells

Abstract

Productivity of wells in South-West Iran has decreased due to completion and production problems in recent decades. This is a large risk against sustainable production from the fields. To allow stable production, an important measure is completion and production optimization including artificial lift methods. This was investigated using simulations validated by pilot field tests. Several case studies were considered in terms of their completion and production. Five scenarios were investigated: natural production through annulus and tubing (scenario-1 and 2), artificial gas lift production through annulus (scenario-3), through tubing using non-standard gas lift (scenario-4) and using standard gas lift (scenario-5). Scenario-1 is currently the case in most wells of the field. To find the optimal scenario and completion/production parameters, simulations of 11 wells of an oilfield in the region were carried out using nodal and sensitivity analysis. The optimized parameters include wellhead pressures (WHPs), tubing dimensions, maximum tolerable water cuts and gas oil ratios and artificial gas injection rate. Simulation results were validated by pilot field tests. In addition, appropriately selected wellhead and Christmas trees for all scenarios were depicted. Simulations confirmed by field pilot tests showed that optimization of completion and production mode and parameters can contribute largely to production improvement. The results showed that the current scenario-1 is the worst of all. However, production through tubing (scenario-2) is optimal for wells which can produce with natural reservoir pressure, with an increase of 800 STB/Day rate per well compared with scenario-1. However, for wells requiring artificial gas lift, the average production rate increase (per well) from the annulus to tubing production was 1185 STB/Day. Next, using the standard gas lift (scenario-5) was found to be the optimal mode of gas lifting and is strongly recommended. WHPs in scenario-5 were the greatest of all, whereas scenario-1 gave the lowest WHPs. The optimal tubing diameter and length were determined. The greatest maximum tolerable water cut was obtained using scenario-5, whereas the lowest was with scenario-1. The maximum tolerable GOR was around 1900 scf/STB. Changing of scenarios did not have significant effect on maximum tolerable GOR. The optimal artificial gas injection rates were found. This validated simulation work proved that completion and production optimization of mode and parameters had considerable contribution to production improvement in South-West Iran. This sequential comprehensive work can be applied in any other field or region. [ABSTRACT FROM AUTHOR]

Published

2021

3. Numerical simulation of water production process and spontaneous imbibition in a fractured gas reservoir – A case study on homa gas field.

Author

Akbarifard, Mohammad Ghasem, Azdarpour, Amin, Aboosadi, Zahra Arab, Honarvar, Bizhan, and Nabipour, Moein

Subjects

GAS fields, GAS reservoirs, MANUFACTURING processes, WATER-gas, GAS wells, HYDRAULICS

Abstract

Water coning in gas production wells generally causes excess water production and many operational problems. This phenomenon is more crucial in fractured reservoirs. The purpose of this study is to investigate this phenomenon by numerical simulation of gas production in a three-dimensional single well model. In order to obtain accurate perception of actual flow behavior, the structure of fracture network consisting of horizontal and vertical fractures defined clearly in the model. The fluid and rock properties of one of the gas fields in south of Iran is used in the model. The performed simulations showed increase of water level around production well due to the high pressure-gradient in the fracture network of reservoir. In addition, evaluation of the impact of various parameters on flow behavior proved that the fracture network plays a significant role in water and gas production in carbonated reservoirs. The results also showed that short-term well closure can not have an important effect on water production problem; but flow rate reduction causes decrease in water production to an acceptable extent. Furthermore, designing suitable depth of completion can also be remarkable in management of water production of gas wells. • The structure of fracture network defined clearly in the model. • Water level increased due to the pressure-gradient in the fracture network of reservoir. • Short-term closure has little impact on water production and reduced flow will reduce. • Water production Flow rate reduction causes decrease in water production. [ABSTRACT FROM AUTHOR]

Published

2020