Water Control in Oil Wells With Downhole Oil-Free Water Drainage and Disposal

Inikori, Solomon O.; Wojtanowicz, Andrew K.; Siddiqi, Sarmad S.

doi:10.2118/77559-ms

Cited by 7 publications

(2 citation statements)

References 10 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Because of reservoir heterogeneity and the “heel-toe” effect, the problems of water coning, short water breakthrough time, and imbalanced production profiles have become the major difficulties that restrict the development of horizontal wells (Figure ). The six main methods of solving these problems are the maximum water-free production rate, annular zone isolation using chemicals, , variable density perforation, , dual horizontal well completion, − stinger completion, , and inflow control device (ICD)/automatic inflow control device (AICD) completion technology. − Figure shows a schematic of ICD/AICD technology, which has been the most popular method in Chinese oil fields over recent years.…”

Section: Introductionmentioning

confidence: 99%

A Novel Automatic Inflow-Regulating Valve for Water Control in Horizontal Wells

Cui

et al. 2020

ACS Omega

View full text Add to dashboard Cite

Horizontal wells are prone to water coning and imbalanced inflow profile problems because of reservoir heterogeneity, the “heel-toe” effect, and different water avoidance heights. To solve these problems, an automatic inflow control device (AICD) technology is developed, as the traditional inflow control device (ICD) technology is frequently invalid after water breakthrough. In this study, a novel water control tool, an automatic inflow-regulating valve (AIRV), was designed to balance inflow profiles before water breakthrough and to limit water inflow after water breakthrough. With the use of a movable part, the AIRV can quickly distinguish fluids and limit the water output based on differences in fluid properties and the swirling flow principle. The water control efficiency and ability of the AIRV were simulated and optimized using computational fluid dynamics (CFD) software and verified experimentally using a water control testing system specially designed for the AIRV. We observed that (1) the total water force on the movable component of the AIRV is notably larger than that of oil because the swirling intensity of water is significantly higher than that of oil; moreover, the force directions of water and oil are opposite to each other. (2) The AIRV is sensitive to the flow rate and fluid viscosity but not to fluid density. (3) A higher water cut results in a higher AIRV pressure loss. The results of the CFD simulation and experimental test demonstrated that the AIRV has a significant water control ability and efficiency, particularly under conditions of a high production rate and high water cut. Thus, the AIRV can be used to enhance the control of water inflow before and after water breakthroughs in horizontal wells.

show abstract

Section: Introductionmentioning

confidence: 99%

A Novel Automatic Inflow-Regulating Valve for Water Control in Horizontal Wells

Cui

et al. 2020

ACS Omega

View full text Add to dashboard Cite

show abstract

“…Similar mechanism is employed in the DWS technology for local control of water coning [34]. Generally, a DWS well has two completions: the top completion is installed in the oil pay zone to produce oil, and the bottom completion is placed in the aquifer to keep the oil water contact (OWC) beneath the top completion [35][36][37][38][39][40]. To date, various versions of DWS technique have been developed by the Downhole Water Sink Technology Initiative (DWSTI) research program at the Louisiana State University (LSU) -including Downhole Water Loop (DWL), and Bilateral Water Sink (BWS) etc.…”

Section: Introductionmentioning

confidence: 99%

Loss and restoration of water coning control – field case history and prediction

Wojtanowicz

Jin

2018

drill

Self Cite

View full text Add to dashboard Cite

A Depletion Strategy for an Active Bottom-Water Drive Reservoir Using Analytical and Numerical Models—Field Case Study

Nashawi

Al-Anzi

Hashem

2009

Journal of Heat Transfer

View full text Add to dashboard Cite

Water coning is one of the most serious problems encountered in active bottom-water drive reservoir. It increases the cost of production operations, reduces the efficiency of the depletion mechanism, and decreases the overall oil recovery. Therefore, preventive measures to curtail water coning damaging effects should be well delineated at the early stages of reservoir depletion. Production rate, mobility ratio, well completion design, and reservoir anisotropy are few of the major parameters influencing and promoting water coning. The objective of this paper is to develop a depletion strategy for an active bottom-water drive reservoir that would improve oil recovery, reduce water production due to coning, delay water breakthrough time, and pre-identify wells that are candidates to excessive water production. The proposed depletion strategy does not only take into consideration the reservoir conditions, but also the currently available surface production facilities and future development plan. Analytical methods are first used to obtain preliminary estimates of critical production rate and water breakthrough time, then comprehensive numerical investigation of the relevant parameters affecting water coning behavior is conducted using a single well 3D radial reservoir simulation model.

show abstract

Water Control in Oil Wells With Downhole Oil-Free Water Drainage and Disposal

Cited by 7 publications

References 10 publications

A Novel Automatic Inflow-Regulating Valve for Water Control in Horizontal Wells

A Novel Automatic Inflow-Regulating Valve for Water Control in Horizontal Wells

Loss and restoration of water coning control – field case history and prediction

A Depletion Strategy for an Active Bottom-Water Drive Reservoir Using Analytical and Numerical Models—Field Case Study

Contact Info

Product

Resources

About