Gravity Drainage Mechanism in Naturally Fractured Carbonate Reservoirs; Review and Application

Faisal Awad Aljuboori,Jang Hyun Lee,Karl D Stephen,Khaled A Elraies

doi:10.3390/en12193699

Faisal Awad Aljuboori, Jang Hyun Lee + Show 2 more

Open Access

https://doi.org/10.3390/en12193699

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Journal: Energies	Publication Date: Sep 27, 2019
Citations: 24	License type: CC BY 4.0

Affiliation: Universiti Teknologi Petronas, Heriot-Watt University

Abstract

Gravity drainage is one of the essential recovery mechanisms in naturally fractured reservoirs. Several mathematical formulas have been proposed to simulate the drainage process using the dual-porosity model. Nevertheless, they were varied in their abilities to capture the real saturation profiles and recovery speed in the reservoir. Therefore, understanding each mathematical model can help in deciding the best gravity model that suits each reservoir case. Real field data from a naturally fractured carbonate reservoir from the Middle East have used to examine the performance of various gravity equations. The reservoir represents a gas–oil system and has four decades of production history, which provided the required mean to evaluate the performance of each gravity model. The simulation outcomes demonstrated remarkable differences in the oil and gas saturation profile and in the oil recovery speed from the matrix blocks, which attributed to a different definition of the flow potential in the vertical direction. Moreover, a sensitivity study showed that some matrix parameters such as block height and vertical permeability exhibited a different behavior and effectiveness in each gravity model, which highlighted the associated uncertainty to the possible range that often used in the simulation. These parameters should be modelled accurately to avoid overestimation of the oil recovery from the matrix blocks, recovery speed, and to capture the advanced gas front in the oil zone.

Highlights

Fossil fuels constitute a significant portion of world energy consumption, and the world demand on this type of energy is expected to grow in the coming decades [1,2]
The gradual reduction in the oil saturation in the matrix represents the oil flow out of the matrix blocks toward the fractures and substituted by the counter flow of the gas as illustrated in Figure 12, which shows the time-lapse of oil saturation changes in the matrix blocks for five years
The oil recovery from the matrix blocks depends on several factors such as matrix block dimensions, vertical permeability, and relative permeability curves that control the speed and recovery factor

Summary

Introduction

Fossil fuels constitute a significant portion of world energy consumption, and the world demand on this type of energy is expected to grow in the coming decades [1,2]. Many major economic sectors are significantly influenced by oil prices. The global oil market has attributed prices as an essential factor to all world economics [3]. The currently producing fields are not able to meet the future increment to the fuel energy demand, which requires an increase in production from low-recovery reservoirs or to develop new prospects. Carbonate reservoirs host about 70% of the conventional oil reserves in the Middle East, and most of them are naturally fractured [4].

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Discussion

Conclusion