Forecasting the Water Flooding for the Production Wells of a Gas Condensate Field with a Fractured Reservoir Type

Mapping Intimacies ◽

10.2118/206578-ms ◽

2021 ◽

Author(s):

Pavel Dmitrievich Gladkov ◽

Anastasiia Vladimirovna Zheltikova

Keyword(s):

Produced Water ◽

Fractured Reservoirs ◽

Gas Condensate ◽

Water Flooding ◽

Fractured Reservoir ◽

Well Performance ◽

Integrated Monitoring ◽

Field Development ◽

Water Gas ◽

Gas Ratio

Abstract As is known, fractured reservoirs compared to conventional reservoirs have such features as complex pore volume structure, high heterogeneity of the porosity and permeability properties etc. Apart from this, the productivity of a specific well is defined above all by the number of natural fractures penetrated by the wellbore and their properties. Development of fractured reservoirs is associated with a number of issues, one of which is related to uneven and accelerated water flooding due to water breakthrough through fractures to the wellbores, for this reason it becomes difficult to forecast the well performance. Under conditions of lack of information on the reservoir structure and aquifer activity, the 3D digital models of the field generated using the hydrodynamic simulators may feature insufficient predictive capability. However, forecasting of breakthroughs is important in terms of generating reliable HC and water production profiles and decision-making on reservoir management and field facilities for produced water treatment. Identification of possible sources of water flooding and planning of individual parameters of production well operation for the purpose of extending the water-free operation period play significant role in the development of these reservoirs. The purpose of this study is to describe the results of the hydrochemical monitoring to forecast the water flooding of the wells that penetrated a fractured reservoir on the example of a gas condensate field in Bolivia. The study contains data on the field development status and associated difficulties and uncertainties. The initial data were results of monthly analyses of the produced water and the water-gas ratio dynamics that were analyzed and compared to the data on the analogue fields. The data analysis demonstrated that first signs of water flooding for the wells of the field under study may be diagnosed through the monitoring of the produced water mineralization - the water-gas ratio (WGR) increase is preceded by the mineralization increase that may be observed approximately a month earlier. However, the data on the analogue fields shows that this period may be longer – from few months to two years. Thus, the hydrochemical method within integrated monitoring of development of a field with a fractured reservoir could be one of the efficient methods to timely adjust the well operation parameters and may extend the water-free period of its operation.

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A Simplified and Efficient Method for Water Flooding Production Index Calculations in Low Permeable Fractured Reservoir

Journal of Energy Resources Technology ◽

10.1115/1.4043788 ◽

2019 ◽

Vol 141 (11) ◽

Cited By ~ 8

Author(s):

Shun Liu ◽

Liming Zhang ◽

Kai Zhang ◽

Jianren Zhou ◽

Heng He ◽

...

Keyword(s):

Fractured Reservoirs ◽

Water Injection ◽

Cross Flow ◽

Production Performance ◽

Water Flooding ◽

Simplified Model ◽

Single Fracture ◽

Fractured Reservoir ◽

Production Index ◽

Future Production

Presently, predicting the production performance of fractured reservoirs is often challenging because of the following two factors: one factor such as complicatedly connected and random distribution nature of the fractures and the other factor includes the limitations of the understanding of reservoir geology, deficient fracture-related research, and defective simulators. To overcome the difficulties of simulating and predicting fractured reservoir under complex circumstances of cross flow, a simplified model, which assumes cross flow only exists in the oil phase segment, is constructed. In the model, the pressure distribution of a single fracture can be described by solving an analytical mathematical model. In addition, due to research and field experience which indicate that cross flow also exists in the mixed-phase segment after water injection, the simplified model is modified to consider cross flow in the whole phase. The model constructed here is applicable for fractured reservoirs especially for a low-permeability fracture reservoir, and it moderately predicts future production index. By using iterative methods, the solution to the model can be feasibly obtained and related production performance index formulas can be derived explicitly. A case study was performed to test the model, and the results prove that it is good.

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A Mathematical Model for Natural Fracture Evolution in Water-Flooding Oil Reservoir

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.868.535 ◽

2013 ◽

Vol 868 ◽

pp. 535-541

Author(s):

Hong Liu ◽

Lin Wang ◽

Yu Wu Zhou ◽

Xi Nan Yu

Keyword(s):

Oil Recovery ◽

Rock Fracture ◽

Fractured Reservoirs ◽

Water Injection ◽

Injection Pressure ◽

Natural Fracture ◽

Water Flooding ◽

Oil Well ◽

Fractured Reservoir ◽

Naturally Fractured

The fractured low permeability reservoirs develop complex fracture network. As the of waterflooding recovery heightens, excessive high injection pressures and excessive water injection rate will result in open, initiation, propagation and coalescence of micro-fracture, connecting injection with production form the high permeability zone, which results in a one-way onrush of waterflooding, water cut in oil well water rise quickly, causing a severe oil well flooding and channeling, thereby reducing the ultimate oil recovery efficiency. The effect of the waterflooding seepage within natural fracture on fracture initiation is studied and analyzed here, applying the theory of rock fracture mechanics to analyze the interaction of fracture system for naturally fractured reservoirs in waterflooding developing process, studying the mechanical mechanism of opening, initiation, propagation and coalescence of natural fracture under injection pressure, which is important theoretical significance for studying the distribution law of fracture and defining appreciate water injection mode and injection pressure in the process of injection development of the naturally fractured reservoir and for delaying the directivity water break-through and water flooding rate of oil well in the process of injection development.

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Generalization of the basic research on the increase of recovery factors in water-drive gas-condensate reservoirs

Prospecting and Development of Oil and Gas Fields ◽

10.31471/1993-9973-2020-3(76)-7-22 ◽

2020 ◽

pp. 7-22

Author(s):

S. V. Matkivskyi ◽

O. R. Kondrat

Keyword(s):

Produced Water ◽

Water Pressure ◽

Experimental Studies ◽

Basic Research ◽

Gas Condensate ◽

Three Dimensional Model ◽

Reservoir Water ◽

Field Development ◽

Capacitive Properties ◽

Residual Gas

The problem of monitoring and preventing deposit inundation is becoming increasingly important in Ukraine. The solution to this problem is one of the ways to ensure the energy independence of the state. The operation of producing wells is complicated by the accumulation of liquid at the bottom. Subsequently, it leads to premature shutdown of the wells. Inundation determines the need to isolate the influx of formation water. Considering the significant residual reserves of gas trapped in water, it is important to improve existing technologies and to develop new ones for the development of depleted fields under the conditions of dynamic water drive in order to ensure maximum hydrocarbon recovery rates. This paper summarizes domestic and foreign field development technologies under water pressure conditions and analyzes the main disadvantages and advantages of the existing methods of stimulating hydrocarbon inflows in waterlogged gas and gas condensate wells. The main factors that determine the causes and nature of flooding of productive formations and ways to prevent them are analyzed. Based on the results of the analysis of laboratory and experimental studies, the behavior of gas trapped by brine water has been established.But the issue of determining the localization of residual reserves has not been studied sufficiently. Considering the above mentioned ideas, the author asserts the necessity to and to use geological and technological models constantly. It ensures better extraction of the residual gas from depleted fields under the condition of intensive advance of reservoir water into productive formations. In the case of adapting the three-dimensional model to the actual data of the production history and the simulation of the exact breakthrough of produced water in production wells, there comes the possible to determine the most promising zones and sections of the field, the reservoirs of which are characterized by the best filtration-capacitive properties and significant gas reserves. The use of a constantly operating geological and technological model of the field will make it possible to develop ways of extracting the residual gas reserves trapped in produced water, to improve existing production technologies and to ensure maximum recovery factors.

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Field classification of fractured reservoirs of crystalline basement

Georesursy ◽

10.18599/grs.2021.3.12 ◽

2021 ◽

Vol 23 (3) ◽

pp. 90-98

Author(s):

Alexander I. Shchekin ◽

Vladimir A. Vasiliev ◽

Alexander S. Nikolaychenko ◽

Andrey V. Kolomiytsev

Keyword(s):

Fractured Reservoirs ◽

Crystalline Basement ◽

Influence Coefficient ◽

Well Performance ◽

Void Space ◽

Field Development ◽

The Impact

Development of oil and gas deposits in fractured reservoirs entails certain risks due to peculiarities of geological structure. Classification and identification of fractures in reservoirs is of high-priority importance and makes it possible to assess the impact of both fractured systems and matrix blocks on field development parameters. This article presents the results of statistical and qualitative analysis of the influence of fracture systems and fracture heterogeneity to classify reservoirs in crystalline basement granitoids using the example of the White Tiger (Bach Ho) and Dragon (Rong) fields located on the southern shelf of the South China Sea (Viet Nam). Field classification of fractured reservoirs is based on a well-marked difference in parameters between wells within a field, due to fracture heterogeneity. In order to solve the tasks set, construction and analysis of graphs of well performance parameters distribution (productivity, flow rates, accumulated indicators, etc.) as well as Lorenz curves were carried out. According to the results, all the objects under study are characterized by asymmetrical shape of distribution curves, which indicates a significant influence of fracturing. Based on the calculated values of the fracture influence coefficient, it is found that fractured reservoirs in crystalline basement, as a first approximation, belong to type 2. This fact is inconsistent with the earlier works on crystalline basement, in which rocks are classified as reservoirs of type 1. Such contradiction is explained by the fact that the microfracture systems and the blocky low-permeability part exhibit matrix properties, but are not fully matrix. This part of the reservoir is proposed to be called a “pseudo-matrix”. If macrocracks dominate in the section, the basement rocks are identified as type 1 fractured reservoirs, but if microfracture systems (“pseudo-matrix”) dominate in some parts of the void space, they may show the properties of type 2 reservoirs forming a mixed type of fractured reservoirs.

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Technology for Improving the Efficiency of Fractured Reservoir Development Using Gel-Forming Compositions

Energies ◽

10.3390/en14248254 ◽

2021 ◽

Vol 14 (24) ◽

pp. 8254

Author(s):

Dmitry Mardashov ◽

Victor Duryagin ◽

Shamil Islamov

Keyword(s):

Fractured Reservoirs ◽

The Arctic ◽

High Tech ◽

Exploratory Research ◽

Fractured Reservoir ◽

Field Development ◽

Oil Reserves ◽

Chemical Reagents ◽

Reservoir Development ◽

Filtration Properties

Increasing the field development efficiency of fractured reservoirs is a contemporary issue. This paper presents fundamental and exploratory research results in this field using modern high-tech experimental equipment from the “Arctic” Scientific Centre at the Saint Petersburg Mining University. Oil reserves in fractured reservoirs are enormous; however, they are classified as hard-to-recover. The before-mentioned reservoirs require a specific approach when selecting technologies to improve the efficiency of their development. In this paper, as a solution to the problem under discussion, we propose the use of a physicochemical method of developing fractured reservoirs based on the injection of a water shut-off agent to exclude highly permeable water-conducting fractures from the drainage process. This technology makes it possible to effectively include and develop previously undrained reservoir areas by directly controlling their filtration properties with the use of new highly efficient and ecologically safe chemical reagents and process fluids.

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THE MAIN SOURCES OF WELLS WATER-FLOODING AND PREDICTION PECULIARITIES OF PRODUCED WATER VOLUMES FROM LITHOLOGICALLY ISOLATED GAS-CONDENSATE DEPOSIT

Oilfield Engineering ◽

10.30713/0207-2351-2018-12-18-23 ◽

2018 ◽

pp. 18-23

Author(s):

M.B. Shinkarev ◽

◽

E.A. Reitblat ◽

N.A. Cheremisin ◽

◽

...

Keyword(s):

Produced Water ◽

Gas Condensate ◽

Water Flooding ◽

Water Volumes

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Recovery Improvement Using Geological, Technical and Operational Factors of Field Development That Influence the Character of Inflow Profiles in Horizontal Laterals

10.2118/204798-ms ◽

2021 ◽

Author(s):

Nadir Husein ◽

Evgeny Malyavko ◽

Igor Novikov ◽

Albina Drobot ◽

Anton Buyanov ◽

...

Keyword(s):

New Technologies ◽

Oil Field ◽

Water Flooding ◽

Well Performance ◽

Efficient Manner ◽

Field Development ◽

Reservoir Performance ◽

Oil Flow ◽

Complicating Factors ◽

Cost Efficient

Abstract Currently, it is hard to imagine oil field development management without various surveys, involving resource optimisation for more economical reserves recovery. In this context, the application of new technologies aimed at diagnostics of the state of producing wells opens up multiple opportunities to identify the causes of premature water flooding and reduction in oil production, clarify the geology of the developed deposit, and obtain other useful information in a cost-efficient manner. For several decades now, well logging has been the source of information for field operators on the producing reservoir performance and the composition of fluid flowing across the reservoir through target intervals. However, in the course of time, the industry tends to seek advanced technologies and alternative production logging techniques for well performance diagnostics. Marker-based production logging is just one of the techniques employed to obtain additional data that can be extremely important for prompt decision-making in case of any complicating factors. At the same time, such information requires proper processing and interpretation. The information on how various factors impact the production profile helps develop a set of measures to adjust the oil flow into the well. In this regard, the task above offers a promising outlook for improving the development system efficiency using selective reservoir stimulation, as far as unconventional reservoirs and hard-to-recover reserves are concerned. Therefore, the upstream industry puts a strong focus on further research in this area today.

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