Water Injection Well Performance and Fracture Propagation in a Channel Sand Reservoir: An Offshore Ghana Case Study

2019 ◽  
Author(s):  
Jongsoo Hwang ◽  
Prateek Bhardwaj ◽  
Mukul Sharma ◽  
Sekhar Sathyamoorthy ◽  
Kwarteng Amaning ◽  
...  
Keyword(s):  
Water Injection ◽  
Fracture Propagation ◽  
Injection Well ◽  
Well Performance

The New Generation of Outflow Control Devices Autonomously Controlling the Conformance of Water Injection Well- A Case Study with ADNOC Onshore

2021 ◽  
Author(s):  
Sultan Ibrahim Al Shemaili ◽  
Ahmed Mohamed Fawzy ◽  
Elamari Assreti ◽  
Mohamed El Maghraby ◽  
Mojtaba Moradi ◽  
...  
Keyword(s):  
Oil Recovery ◽  
Dynamic Properties ◽  
Short Circuit ◽  
Water Injection ◽  
Performance Outcomes ◽  
Injection Well ◽  
Well Performance ◽  
Injection Wells ◽  
Horizontal Section ◽  
Control Devices

Abstract Several techniques have been applied to improve the water conformance of injection wells to eventually improve field oil recovery. Standalone Passive flow control devices or these devices combined with Sliding sleeves have been successful to improve the conformance in the wells, however, they may fail to provide the required performance in the reservoirs with complex/dynamic properties including propagating/dilating fractures or faults and may also require intervention. This is mainly because the continuously increasing contrast in the injectivity of a section with the feature compared to the rest of the well causes diverting a great portion of the injected fluid into the thief zone which ultimately creates short-circuit to the nearby producer wells. The new autonomous injection device overcomes this issue by selectively choking the injection of fluid into the growing fractures crossing the well. Once a predefined upper flowrate limit is reached at the zone, the valves autonomously close. Well A has been injecting water into reservoir B for several years. It has been recognised from the surveys that the well passes through two major faults and the other two features/fractures with huge uncertainty around their properties. The use of the autonomous valve was considered the best solution to control the water conformance in this well. The device initially operates as a normal passive outflow control valve, and if the injected flowrate flowing through the valve exceeds a designed limit, the device will automatically shut off. This provides the advantage of controlling the faults and fractures in case they were highly conductive as compared to other sections of the well and also once these zones are closed, the device enables the fluid to be distributed to other sections of the well, thereby improving the overall injection conformance. A comprehensive study was performed to change the existing dual completion to a single completion and determine the optimum completion design for delivering the targeted rate for the well while taking into account the huge uncertainty around the faults and features properties. The retrofitted completion including 9 joints with Autonomous valves and 5 joints with Bypass ICD valves were installed in the horizontal section of the well in six compartments separated with five swell packers. The completion was installed in mid-2020 and the well has been on the injection since September 2020. The well performance outcomes show that new completion has successfully delivered the target rate. Also, the data from a PLT survey performed in Feb 2021 shows that the valves have successfully minimised the outflow toward the faults and fractures. This allows achieving the optimised well performance autonomously as the impacts of thief zones on the injected fluid conformance is mitigated and a balanced-prescribed injection distribution is maintained. This paper presents the results from one of the early installations of the valves in a water injection well in the Middle East for ADNOC onshore. The paper discusses the applied completion design workflow as well as some field performance and PLT data.

An Integrated IR4.0 Software Enables Autonomous Casing Crossflow Rate Calculation

2021 ◽  
Author(s):  
Nasser M. Al-Hajri ◽  
Akram R. Barghouti ◽  
Sulaiman T. Ureiga
Keyword(s):  
Industrial Revolution ◽  
Water Injection ◽  
Flow Characteristics ◽  
Injection Rate ◽  
Performance Model ◽  
Injection Well ◽  
Production Model ◽  
Well Performance ◽  
Secondary Formation ◽  
Well Model

Abstract This paper will present an alternative calculation technique to predict wellbore crossflow rate in a water injection well resulting from a casing leak. The method provides a self-governing process for wellbore related calculations inspired by the fourth industrial revolution technologies. In an earlier work, calculations techniques were presented which do not require the conventional use of downhole flowmeter (spinner) to obtain the flow rate. Rather, continuous surface injection data prior to crossflow development and shut-in well are used to estimate the rate. In this alternative methodology, surface injection data post crossflow development are factored in to calculate the rate with the same accuracy. To illustrate the process an example water injector well is used. To quantify the casing leak crossflow rate, the following calculation methodology was applied:Generate a well performance model using pre-crossflow injection data. Normal modeling techniques are applied in this step to obtain an accurate model for the injection well as a baseline case.Generate an imaginary injection well model: An injection well mimicking the flow characteristics and properties of the water injector is envisioned to simulate crossflow at flowing (injecting) conditions. In this step, we simulate an injector that has total depth up to the crossflow location only and not the total depth of the example water well.Generate the performance model for the secondary formation using post crossflow data: The total injection rate measured at surface has two portions: one portion goes into the shallower secondary formation and another goes into the deeper (primary) formation. The modeling inputs from the first two steps will be used here to obtain the rate for the downhole formation at crossflow conditions.Generate an imaginary production well model: The normal model for the water injector will be inversed to obtain a production model instead. The inputs from previous steps will be incorporated in the inverse modeling.Obtaining the crossflow rate at shut-in conditions: Performance curves generated from step 3 & 4 will be plotted together to obtain an intersection that corresponds to the crossflow rate at shut-in conditions. This numerical methodology was analytically derived and the prediction results were verified on syntactic field data with very high accuracy. The application of this model will benefit oil operators by avoiding wireline logging costs and associated safety risks with mechanical intervention.

Water Hammer Effects on Water Injection Well Performance and Longevity

2008 ◽  
Author(s):  
Xiuli Wang ◽  
Knut Arne Hovem ◽  
Daniel Moos ◽  
Youli Quan
Keyword(s):  
Water Injection ◽  
Water Hammer ◽  
Injection Well ◽  
Well Performance

scholarly journals EVOLUTION OF THE COLUMN FOULING PRODUCTION IN WELLS PRODUCING OIL END GAS: CASE STUDY

2014 ◽  
Vol 12 (24) ◽  
pp. 64-70
Author(s):  
Fernando Nunes DA SILVA ◽  
Jardel Dantas DA CUNHA ◽  
Andréa Francisca Fernandes BARBOSA ◽  
Djalma Ribeiro DA SILVA
Keyword(s):  
Formation Mechanism ◽  
Temperature Increase ◽  
Water Injection ◽  
Soxhlet Extraction ◽  
Oil Industry ◽  
Scale Formation ◽  
Injection Well ◽  
Extraction Techniques ◽  
Bicarbonate Ions

In the oil industry the problem of scale formation causes a lot of damage, including the reduction in the production of liquid and thus can be cited oil, also with the increased costs for the production there of. The study of scale is then of paramount importance for the understanding of their formation mechanism and the choice of method for prevention and / or removal. Soxhlet extraction techniques EFRX, XRD and SEM were used to characterize a sample collected in the column of producing a water injection well. Through the analysis of the results was identified scale ferruginous type which its formation is associated with the presence of corrosive agents; and carbonate type, and its formation influenced by the concentration of calcium and bicarbonate ions dissolved in the water , since such formation is common in wells which have a high content of these ions , which is also favored by decreasing the pressure and temperature increase reservoir

scholarly journals Acquiring and utilizing the wellbore data to recover the well performance-In the case of Yufutsu water injection well-

2010 ◽  
Vol 75 (6) ◽  
pp. 428-435
Author(s):  
Tanetomo Izumi ◽  
Koji Hosokoshi ◽  
Naoyuki Wakabayashi
Keyword(s):  
Water Injection ◽  
Injection Well ◽  
Well Performance

A Case Study of Water Injection Well Stimulation in a Low Permeability Oil Reservoir

2016 ◽  
Author(s):  
J. R. Shaoul ◽  
W. J. Spitzer ◽  
S. Fekkai ◽  
L. Sepulveda
Keyword(s):  
Water Injection ◽  
Injection Well ◽  
Low Permeability ◽  
Oil Reservoir ◽  
Well Stimulation

A New Method of Fall-Off Test in Water Injection Well in Tahe Oilfield

2013 ◽  
Vol 807-809 ◽  
pp. 2508-2513
Author(s):  
Qiang Wang ◽  
Wan Long Huang ◽  
Hai Min Xu
Keyword(s):  
Water Injection ◽  
Injection Well ◽  
Well Test ◽  
Well Bore ◽  
Residual Oil ◽  
Injection Wells ◽  
Oil Saturation ◽  
Tahe Oilfield ◽  
Fitting Method ◽  
Front Radius

In pressure drop well test of the clasolite water injection well of Tahe oilfield, through nonlinear automatic fitting method in the multi-complex reservoir mode for water injection wells, we got layer permeability, skin factor, well bore storage coefficient and flood front radius, and then we calculated the residual oil saturation distribution. Through the examples of the four wells of Tahe oilfield analyzed by our software, we found that the method is one of the most powerful analysis tools.

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