Application of Phase Change Tracking Approach in Predicting Condensate Blockage in Tight, Low, and High Permeability Reservoirs

Onoabhagbe, Benedicta Bilotu; Russell, Paul; Ugwu, Johnson; Gomari, Sina Rezaei

doi:10.3390/en13246551

Cited by 4 publications

(3 citation statements)

References 21 publications

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“…Due to the complex phase and fluid flow behavior of these reservoirs, their evaluation becomes a challenging issue. With condensate accumulation around the well, the effective permeability is reduced substantially [38,[57][58][59][60][61][62][63][64][65][66][67][68].…”

Section: Gas Condensate Reservoirs and Pressure Transientmentioning

confidence: 99%

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Numerical Well Test Analysis of Condensate Dropout Effects in Dual-Permeability Model of Naturally Fractured Gas Condensate Reservoirs: Case Studies in the South of Iran

Safari-Beidokhti¹,

Hashemi

Abdollahi³

et al. 2021

Mathematical Problems in Engineering

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Naturally fractured reservoirs (NFR) represent an important percentage of worldwide hydrocarbon reserves and production. The performance of naturally fractured gas condensate reservoirs would be more complicated regarding both rock and fluid effects. In contrast to the dual-porosity model, dual-porosity/dual-permeability (dual-permeability) model is considered as a modified model, in which flow to the wellbore occurs through both matrix and fracture systems. Fluid flow in gas condensate reservoirs usually demonstrates intricate flow behavior when the flowing bottom-hole pressure falls below the dew point. Accordingly, different regions with different characteristics are formed within the reservoir. These regions can be recognized by pressure transient analysis. Consequently, distinguishing between reservoir effects and fluid effects is challenging in these specific reservoirs and needs numerical simulation. The main objective of this paper is to examine the effect of condensate banking on the pressure behavior of lean and rich gas condensate NFRs through a simulation approach. Subsequently, evaluation of early-time characteristics of the pressure transient data is provided through a single well compositional simulation model. Then, drawdown, buildup, and multirate tests are conducted to establish the condition in which the flowing bottom-hole pressure drops below the dew point causing retrograde condensation. The simulation results are confirmed through well test analysis in both Iranian naturally fractured rich and lean gas condensate fields. Interpretations of simulation analysis revealed that the richer gas is more prone to condensation. When the pressure drops below the dew point, the pressure derivative curves in the rich gas system encounter a more shift to the right, and the trough becomes more pronounced as compared to the lean one.

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Section: Gas Condensate Reservoirs and Pressure Transientmentioning

confidence: 99%

“…ree-region composite is the most frequently used model in the gas condensate reservoir evaluation [42,52,56,[58][59][60][61][62][63].…”

Section: Gas Condensate Reservoirs and Pressure Transientmentioning

confidence: 99%

Numerical Well Test Analysis of Condensate Dropout Effects in Dual-Permeability Model of Naturally Fractured Gas Condensate Reservoirs: Case Studies in the South of Iran

Safari-Beidokhti¹,

Hashemi

Abdollahi³

et al. 2021

Mathematical Problems in Engineering

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show abstract

“…To study the retrograde phenomenon and assess its impact on the yield during the development of condensate gas reservoirs, substantial research has been conducted on condensate gas phase characteristics, the evaluation of retrograde pollution, and the impact of retrograde pollution on production, which has mainly been carried out through physical experiments and numerical simulation methods [8][9][10][11]. In relation to the phase characteristics of condensate gas reservoirs, Onoabhagbe et al [12] propose a novel approach for tracking the phase change based on simulating the formation of condensate blockage in tight as well as low-and high-permeability reservoirs; Wang et al [13] improve the Peng-Robinson model to simulate the phase change of condensate gas and calculate the Processes 2024, 12, 522 2 of 14 volume of condensate oil considering the effect of capillary forces; and Abbasov et al [14] analyze the influence of gas components on the retrograde condensation of condensate gas based on the results of retrograde condensation simulation experiments. During the evaluation of retrograde pollution, Dinariev and Evseev [15] construct a condensate liquid production model for the multicomponent flow of condensate gas based on the dynamic characteristics of the condensate gas phase change.…”

Section: Introductionmentioning

confidence: 99%

A Novel Method for the Quantitative Evaluation of Retrograde Condensate Pollution in Condensate Gas Reservoirs

Zhao,

Zhang,

Gao

et al. 2024

Processes

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During the development of condensate gas reservoirs, the phenomenon of retrograde condensation seriously affects the production of gas wells. The skin factor caused by retrograde condensation pollution is the key to measuring the consequent decrease in production. In this study, a multiphase flow model and a calculation model of retrograde condensate damage are first constructed through a dynamic simulation of the phase behavior characteristics in condensate gas reservoirs using the skin coefficient, and these models are then creatively coupled to quantitatively evaluate retrograde condensation pollution. The coupled model is solved using a numerical method, which is followed by an analysis of the effects of the selected formation and engineering parameters on the condensate saturation distribution and pollution skin coefficient. The model is verified using actual test data. The results of the curves show that gas–liquid two-phase permeability has an obvious effect on well production. When the phase permeability curve changes from the first to the third type, the skin coefficient increases from 3.36 to 26.6, and the condensate precipitation range also increases significantly. The distribution of the pollution skin coefficient also changes significantly as a result of variations in the formation and dew point pressures, well production, and formation permeability. The average error between the calculated skin of the model and the actual test skin is 3.87%, which meets the requirements for engineering calculations. These results have certain significance for guiding well test designs and the evaluation of condensate gas well productivity.

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Performance analysis of various machine learning algorithms for CO2 leak prediction and characterization in geo-sequestration injection wells

Harati,

Rezaei Gomari,

Rahman

et al. 2024

Process Safety and Environmental Protection

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Application of Phase Change Tracking Approach in Predicting Condensate Blockage in Tight, Low, and High Permeability Reservoirs

Cited by 4 publications

References 21 publications

Numerical Well Test Analysis of Condensate Dropout Effects in Dual-Permeability Model of Naturally Fractured Gas Condensate Reservoirs: Case Studies in the South of Iran

Numerical Well Test Analysis of Condensate Dropout Effects in Dual-Permeability Model of Naturally Fractured Gas Condensate Reservoirs: Case Studies in the South of Iran

A Novel Method for the Quantitative Evaluation of Retrograde Condensate Pollution in Condensate Gas Reservoirs

Performance analysis of various machine learning algorithms for CO2 leak prediction and characterization in geo-sequestration injection wells

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