Evaluation of water coning phenomenon in naturally fractured oil reservoirs

Azim, Reda Abdel

doi:10.1007/s13202-015-0185-7

Cited by 16 publications

(9 citation statements)

References 17 publications

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“…Fang et al (2017) addressed a similar problem for a gas reservoir. Their observation differs from that of Reda is that, whereas Reda (2016) claims that oil reservoir aquifer strength has a little effect on produced water cut, Fang et al (2017) found great impact of aquifer size and strength on gas productivity and water cut, possibly because of higher dissolved gas in water.…”

Section: Introductionmentioning

confidence: 73%

“…Inamullah et al (2015) have shown through simulation that optimum oil production rate is to be reduced to half of that of maximum production rate if the coning effect is to be minimized. Controlling water coning in fractured reservoirs is more challenging than the homogeneous reservoirs because of the rapid movement of water through the fractures (Reda 2016). To counter the problem, Dabiri et al (2017) suggested the benefits of horizontal wells over vertical wells, showing (through simulation) that critical oil production rate in horizontal wells is greater than that of vertical wells in fractured formations.…”

Section: Introductionmentioning

confidence: 99%

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Controlling excess water production in fractured carbonate reservoirs: chemical zonal protection design

Ghosh

Ali

Belhaj

2020

J Petrol Explor Prod Technol

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Fractured carbonate reservoirs are prone to premature water cut production at the early stage of recovery. Conventionally completed long horizontal wells, suffering from high water cut through fracture networks, need reliable and cost-effective treatment solutions to control water entry, without damaging oil-saturated segments. Protection of oil flow channels from polymer gel invasion could be a challenge in complex fractured reservoirs because of the enormity of the number of zones that may require damage protection. In this work, a chemical package system is developed, comprising three different chemical solutions. The first fluid is designed to protect the low-permeable oil-saturated zones by creating an impermeable barrier while keeping the water conductive fractures open, followed by a gelant, designed to invade, solidify, and seal off the water conductive fractures. The third treatment is designed for a complete dissolution of the protective barrier created by the first fluid. The effectiveness of this process is evaluated through a set of four core flood studies at reservoir conditions. It was observed that whereas the effective brine permeability could be reduced by 74-91%, oil effective permeability is reduced by 12-17% depending on the fracture aperture. The paper also discusses the key parameters to be addressed for successful field implementation of this technology.

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Section: Introductionmentioning

confidence: 73%

Section: Introductionmentioning

confidence: 99%

Controlling excess water production in fractured carbonate reservoirs: chemical zonal protection design

Ghosh

Ali

Belhaj

2020

J Petrol Explor Prod Technol

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“…In a fractured reservoir, controlling water intrusion is challenging due to the complexity that originates from a large number of uncertain variables associated with the representativity of the natural fractures' attributes and spatial distributions. These water intrusion occurrences have been observed and evaluated for a long time by many studies [4][5][6][7][8][9]. Sheng et al [4] present a parametric study that analyses the effect of matrix and fracture permeability, well penetration, vertical anisotropy, aquifer size and gas rate production on water intrusion.…”

Section: Introductionmentioning

confidence: 99%

Water Intrusion Characterization in Naturally Fractured Gas Reservoir Based on Spatial DFN Connectivity Analysis

Chen

Torres

Xing

et al. 2020

Preprint

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In this study, the non-intrusive embedded discrete fracture model (EDFM) in combination with the Oda method are employed to characterize natural fracture networks fast and accurately, by identifying the dominant water flow paths through spatial connectivity analysis. The purpose of this study is to present a successful field case application in which a novel workflow integrates field data, discrete fracture network (DFN), and production analysis with spatial fracture connectivity analysis to characterize dominant flow paths for water intrusion in a field-scale numerical simulation. Initially, the water intrusion of single-well sector models was history matched. Then, resulting parameters of the single-well models were incorporated into the full field model, and the pressure and water breakthrough of all the producing wells were matched. Finally, forecast results were evaluated. Consequently, one of the findings is that wellbore connectivity to the fracture network has a considerable effect on characterizing the water intrusion in fractured gas reservoirs. Additionally, dominant water flow paths within the fracture network, easily modeled by EDFM as effective fracture zones, aid in understanding and predicting the water intrusion phenomena. Therefore, fracture clustering as shortest paths from the water contacts to the wellbore endorses the results of the numerical simulation. Finally, matching the breakthrough time depends on merging responses from multiple dominant water flow paths within the distributions of the fracture network. The conclusions of this investigation are crucial to field modeling and the decision-making process of well operation by anticipating water intrusion behavior through probable flow paths within the fracture networks.

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“…Water invasion is a complex phenomenon observed in oil and gas reservoirs, which will occur due to pressure gradients close to the production well and the imbalance between the viscous and gravity forces around the completion interval [7,8]. There are three essential forces controlling the mechanism, which includes the capillary, viscous and gravity forces [6].…”

Section: Introductionmentioning

confidence: 99%

“…Hu et al [20] and Shen et al [21] used reservoir cores to analyze the effects of different aquifers on water invasion. Azim [7] proposed a fully coupled poroelastic multiphase fluidflow numerical model to understand the water coning phenomenon in naturally fractured reservoir under the effects of various rock and fluid properties. So far there has been a lot of research work carried out on the performance of water invasion in gas reservoirs.…”

Section: Introductionmentioning

confidence: 99%

Experimental Study on the Physical Simulation of Water Invasion in Carbonate Gas Reservoirs

et al. 2017

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Water invasion in carbonate gas reservoirs often results in excessive water production, which limits the economic life of gas wells. This is influenced by reservoir properties and production parameters, such as aquifer, fracture, permeability and production rate. In this study, seven full diameter core samples with dissolved pores and fractures were designed and an experimental system of water invasion in gas reservoirs with edge and bottom aquifers was established to simulate the process of water invasion. Then the effects of the related reservoir properties and production parameters were investigated. The results show that the edge and bottom aquifers supply the energy for gas reservoirs with dissolved pores, which delays the decline of bottom-hole pressure. The high water aquifer defers the decline of water invasion in the early stage while the big gas production rate accelerates water influx in gas reservoirs. The existence of fractures increases the discharge area of gas reservoirs and the small water influx can result in a substantial decline in recovery factor. With the increase of permeability, gas production rate has less influence on recovery factor. These results can provide insights into a better understanding of water invasion and the effects of reservoir properties and production parameters so as to optimize the production in carbonate gas reservoirs.

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Evaluation of water coning phenomenon in naturally fractured oil reservoirs

Cited by 16 publications

References 17 publications

Controlling excess water production in fractured carbonate reservoirs: chemical zonal protection design

Controlling excess water production in fractured carbonate reservoirs: chemical zonal protection design

Water Intrusion Characterization in Naturally Fractured Gas Reservoir Based on Spatial DFN Connectivity Analysis

Experimental Study on the Physical Simulation of Water Invasion in Carbonate Gas Reservoirs

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