The Effect of Fracturing Fluid Saturation on Natural Gas Flow Behavior in Tight Reservoirs

Meng, Mianmo; Shen, Yinghao; Ge, Hongkui; Xu, Xiaosong; Yang, Wenjing

doi:10.3390/en13205278

Cited by 4 publications

(2 citation statements)

References 41 publications

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“…After soaking, the weight of the saturated sample was measured. Permeability was tested by a piece of conventional permeability equipment, and the detailed schematic diagram can be found in Meng et al 45 The measurement principle of permeability was based on measuring the gas flow volume per minute. The confining pressure was 5 MPa, imposed by water, and the pore pressure was 0.25 MPa, imposed by nitrogen.…”

Section: Samples' Background and Experimental Methodsmentioning

confidence: 99%

Rock Fabric of Tight Sandstone and Its Influence on Irreducible Water Saturation in Eastern Ordos Basin

Meng

Shen

et al. 2023

Energy Fuels

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After flowback, the residual fracturing fluid will reduce the gas seepage space and influence natural gas production, which attracts widespread attention. In this study, the irreducible water saturation was investigated, and its controlling factors were clarified. We target the Upper Paleozoic Taiyuan and Shihezi Formations, which belong to a tight gas reservoir in the eastern Ordos Basin. The main experiments include porosity, permeability, mineral composition, nitrogen adsorption, mercury intrusion porosimetry, nuclear magnetic resonance, and high-speed centrifugation. The specific surface area is very low and varies from 0.95 to 4.03 m 2 /g, and the median pore-throat diameter ranges from 28.6 to 698.6 nm. Through the T 2 cutoff value, the water saturation can be divided into movable water saturation (S mov ) and irreducible water saturation (S irr ). Furthermore, the S irr can be divided into water saturation in large pores controlled by the small throat (S irrl ) and water saturation controlled by the capillary force (S irrc ). In both formations, the S irr has a negative relationship with porosity, permeability, and average pore diameter and exhibits a positive relationship with the specific surface area. The S irrl has a positive relationship with the median pore-throat diameter in Taiyuan Formation, but the S irrl has a weak relationship with the median pore-throat diameter in Shihezi Formation. The S irrc has a negative relationship with porosity, permeability, and average pore diameter and displays a positive relationship with the specific surface area in Taiyuan Formation, but the S irrc has a weak relationship with these parameters in Shihezi Formation. The relationship difference between Taiyuan and Shihezi Formations was mainly caused by the pore structure, demonstrated by the amplitude ratio in three peaks. Based on the above analysis, this study is conducive to understanding the mechanism of water occurrence and its controlling factors.

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Section: Samples' Background and Experimental Methodsmentioning

confidence: 99%

Rock Fabric of Tight Sandstone and Its Influence on Irreducible Water Saturation in Eastern Ordos Basin

Meng

Shen

et al. 2023

Energy Fuels

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“…The movable water saturation in tight reservoirs is a vital parameter that signifies water production capacity and is intricately linked to gas well water production characteristics [12,25,26]. In experimental research on formation water mobility, scholars often employ methods such as X-ray diffraction, scanning electron microscopy, and centrifugation combined with nuclear magnetic resonance [27][28][29].…”

Section: Introductionmentioning

confidence: 99%

Research on Transformation of Connate Water to Movable Water in Water-Bearing Tight Gas Reservoirs

Chen,

Wang,

et al. 2023

Energies

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The Dongsheng gas field is a water-bearing tight gas reservoir characterized by high connate water saturation. During gas production, the transformation of connate water into movable water introduces a unique water production mode, significantly impacting gas reservoir recovery. Current experimental and theoretical methods for assessing formation water mobility are static and do not address the transformation mechanism from connate into movable water. In this study, we considered dynamic changes in formation stress and proposed the mechanism for the transformation of connate water into movable water during depressurization, involving the expansion of connate water films and the reduction of pore volume. We developed a novel methodology to calculate the dynamic changes in movable and connate water saturation in tight reservoirs due to reservoir pressure reduction. Furthermore, we quantitatively evaluated the transformation of connate water into movable water in the Dongsheng gas field through laboratory experiments (including formation water expansion tests, connate water tests, and porosity stress sensitivity tests) and theoretical calculations. Results show that under original stress, the initial connate water saturation in the Dongsheng gas field ranges from 50.09% to 58.5%. As reservoir pressure decreases, the maximum increase in movable water saturation ranges from 6.1% to 8.4% due to the transformation of connate water into movable water. This explains why formation water is produced in large quantities during gas production. Therefore, considering the transition of connate water to movable water is crucial when evaluating water production risk. These findings offer valuable guidance for selecting optimal well locations and development layers to reduce reservoir water production risks.

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Observation via Particle Image Velocity (PIV) Technology of Seepage Features in Replicas of Rock Fractures

Xu,

Lei,

Huaiguang

et al. 2024

Rock Mech Rock Eng

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The Effect of Fracturing Fluid Saturation on Natural Gas Flow Behavior in Tight Reservoirs

Cited by 4 publications

References 41 publications

Rock Fabric of Tight Sandstone and Its Influence on Irreducible Water Saturation in Eastern Ordos Basin

Rock Fabric of Tight Sandstone and Its Influence on Irreducible Water Saturation in Eastern Ordos Basin

Research on Transformation of Connate Water to Movable Water in Water-Bearing Tight Gas Reservoirs

Observation via Particle Image Velocity (PIV) Technology of Seepage Features in Replicas of Rock Fractures

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