Permeability Enhancement via Acetic Acid (CH<sub>3</sub>COOH) Acidizing in Coals Containing Fracture-Filling Calcite

Chen, Qiang; Wang, Qinghui

doi:10.1021/acs.energyfuels.1c02199

Cited by 20 publications

(7 citation statements)

References 70 publications

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“…However, only 5–50% of the injected fracturing water returns to the surface after the fracturing process due to leak-off and capillary imbibition from the fracture face into the shale matrix. − Recent experimental observations suggest that because shale formation exhibits ultra-low initial water saturation and high clay content, the imbibed water and clay swelling may block the gas transport pathway in the shale matrix (Figure ), thus preventing migration of shale gas to the fracture. − The impact of retained fracturing water on shale gas transport (gas diffusivity and permeability) has been evaluated in many published literature studies. Chen et al (2022) reported 57% reduction in diffusivity when Longmaxi organic-rich shale was exposed to water for 48 h. A similar blockage effect was also documented in many other organic-rich tight rocks dominated by nanopore systems. − The negative effect on matrix permeability is also observed to be a drastic reduction when exposed to water. For example, Chakraborty et al reported that the matrix permeability of Marcellus and Haynesville shale core plugs was observed to be a reduction of as much as 90–99% due to counter-current spontaneous imbibition of fracturing water .…”

Section: Introductionmentioning

confidence: 80%

Heating-Induced Enhancement of Shale Gas Transport and Its Application for Improving Hydraulic Fracturing Performance

et al. 2022

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Enhancing the gas transport capacity of shale is essential to obtain economical gas production. Thermal stimulation has been theoretically and experimentally proven as a feasible technology for improving shale gas extraction. In this work, Longmaxi organic-rich shale samples were heated at 200−1000 °C for 240 h to investigate the feasibility of heating-induced generation of additional gas transport pathways and improvement of gas transport capacity (diffusivity and permeability) within the shale matrix. Results show that the mass loss of shale samples is basically unchanged after 200 °C, while a significant mass loss ranging from 3.5 to 14.4% can be observed in the heat treatment at 400−1000 °C. Decomposition (e.g., organic matter, calcite, and dolomite) and clay dehydration are the primary causes of shale mass loss. The organic matter in the shale remained unchanged after 200 °C heat treatment but greatly reduced, until almost disappeared, after 400 and 600 °C heat treatments, and the content of carbonate minerals dropped sharply, until almost disappeared, after 600−1000 °C heat treatment. Nitrogen adsorption experiments and in situ scanning electron microscopy observations show a significant improvement of pore volume and pore size after 400−600 °C heat treatment. However, the mineral melt and recrystallization after the heat treatment at 800 and 1000 °C can cause pore destruction and densification, resulting in pore volume decrease, indicating that the best heating temperature in Longmaxi shale samples is around 600 °C to enhance the pore volume and connectivity in the shale matrix. The methane adsorption decreased by 63.0%, the effective diffusion coefficient in the macropore increased by 263 times after 600 °C, and the permeability increased by 212.8 times at 5 MPa confining pressure. The newly formed transport pathways derived from 600 °C heat treatment may also improve shale matrix permeability at a high effective stress ranging from 30 to 65 MPa, which is a typical stress condition in the shale formations 2000−4500 m in depth. Based on the experimental results in this study, we proposed the heat treatment to improve hydraulic fracturing performance by mitigating fracturing-induced formation damage (e.g., water blockage, clay swelling, and secondary precipitation) within the fracture−matrix interface. In situ combustion of shale gas in hydraulic fractures may be a possible method to heat the shale formations and generate heating-induced transport pathways on the wall surfaces of hydraulic fractures.

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Section: Introductionmentioning

confidence: 80%

Heating-Induced Enhancement of Shale Gas Transport and Its Application for Improving Hydraulic Fracturing Performance

et al. 2022

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“…Combined with tomography method, the fault location accuracy can be further improved (Dong et al, 2022). As a typical water and gas channel (Chen et al, 2021;Tian et al, 2022), the fault can be further monitored by acoustic emission method after positioning by LFVS method (Rui et al, 2022a;Rui et al, 2022b).…”

Section: Discussionmentioning

confidence: 99%

A fault location method based on polarization analysis for coal mine

Zeng

Wang²,

Xin³

et al. 2023

Front. Earth Sci.

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A fault is a main cause for water inrush in coal mines. The detection of faults plays an important role in the prevention and governance of water inrush in coal mines. It is hard to determine the direction of seismic wave propagation under the condition of full space of mines, leading to difficulty in accurate fault detection. This paper compares and analyzes the polarization information extraction capability of time-domain polarization analysis, frequency-domain polarization analysis, and time-frequency (TF)-domain polarization analysis, and proposes a TF-domain polarization analysis-based method for locating faults in coal mines. Firstly, the polarization analysis of signals mixed in the time domain was carried out. The results of three kinds of polarization analysis show that the TF-domain polarization analysis can accurately determine the polarization direction of multi-type signals in the case of aliasing. Secondly, a time-space-domain high-order three-dimensional three-component numerical simulation experiment was conducted. The TF-domain polarization analysis was adopted to extract the polarization information of each geophone and locate the fault. The error of the predicted fault strike was 0.16°, and the distance deviation was about 2.03%. Finally, in-situ three-component seismic signals of coal mine were used to predict the location and strike of fault. The data from on-site actual drilling verified the effectiveness of the mine fault location method based on the TF-domain polarization analysis. The predicted fault strike is consistent with the drilling data, and the distance deviation is about 5.5%.

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“…During the development of coalbed methane (CBM), the production of coal fines is a common occurrence due to the low elastic modulus and hardness of coal, which make it susceptible to stress-induced fragmentation. − Coal fines have a tendency to aggregate and settle to different extents when the fluid is discharged, resulting in the retention of coal fines within fractures, blockage of fractures, and reduction of coal reservoir permeability. , The aggregation of coal fines in the wellbore and their entry into the discharge system can result in the entrapment of pumps and subsequent pump failures, which significantly hamper the efficient development of CBM. − During CBM development, the generation of coal fines is influenced by various factors. − Fluids of different natures, such as groundwater, drilling fluid, fracturing fluid, etc., are exposed in the reservoir and propped fractures. Physical or chemical reactions between the fluids and reservoir rock can affect the generation, migration, and production of coal fines. − The inorganic mineral content of coal fines produced from coalbed methane wells in the Hancheng block can be as high as fifty percent. − As a result, these inorganic minerals significantly impact the migration of coal fines in CBM wells. , …”

Section: Introductionmentioning

confidence: 99%

Experimental Study on the Influence of Hydrochemical Properties on the Migration of Coal Fines Containing Kaolinite in Propped Fractures

et al. 2023

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Coal fines generation poses significant challenges to the efficient extraction of coalbed methane. This study aims to investigate the influence of various hydrochemical properties on the migration of coal fines containing kaolinite within propped fractures. Experimental tests are conducted using a coal sample from the No.3 coal seam in the Shanxi Formation of the Hancheng mining area. The fracture permeability, variation of mass concentration, particle size distribution, and morphology of the produced fines are analyzed. The results show that under the same hydrochemical conditions of both Na 2 SO 4 and MgCl 2 solutions, the increase of salinity leads to the increased mass concentration of the produced fines, the increased permeability of the core sample, and the decreased particle size of the produced fines. Under the same salinity (10,000 mg/L) conditions, the mass concentration of coal fines produced using the Na 2 SO 4 solution is higher than that of the MgCl 2 solution, the permeability of the sample is larger, and the particle size of the produced fines is smaller. Kaolinite added to coal fines increases the hydrophilicity and promotes coal fines migration. The presence of metal cations enhances the aggregation of particles. The average sizes of the produced fines exhibit an increase ranging from 14.81 to 49.41%. Similarly, the D90 values exhibit an increase within the range of 0.42−34.90%. The aggregation effect of Mg 2+ on coal fines is greater than that of Na + . Coal fines migration dredges the propped fractures, leading to an increase in permeability. Coal fines aggregate and block fractures, resulting in pressure rise, which yields a decrease in permeability. In cases where the fines aggregation effect dominates, the aggregated fines tend to remain in their initial position within the sample throughout the experiment. Conversely, if the fines migration effect prevails, the coal fines tend to migrate toward the end of the sample, causing end blockage. This research sheds light on potential strategies for effectively managing and controlling coal fines.

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Permeability Enhancement via Acetic Acid (CH₃COOH) Acidizing in Coals Containing Fracture-Filling Calcite

Cited by 20 publications

References 70 publications

Heating-Induced Enhancement of Shale Gas Transport and Its Application for Improving Hydraulic Fracturing Performance

Heating-Induced Enhancement of Shale Gas Transport and Its Application for Improving Hydraulic Fracturing Performance

A fault location method based on polarization analysis for coal mine

Experimental Study on the Influence of Hydrochemical Properties on the Migration of Coal Fines Containing Kaolinite in Propped Fractures

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Permeability Enhancement via Acetic Acid (CH3COOH) Acidizing in Coals Containing Fracture-Filling Calcite

Cited by 20 publications

References 70 publications

Heating-Induced Enhancement of Shale Gas Transport and Its Application for Improving Hydraulic Fracturing Performance

Heating-Induced Enhancement of Shale Gas Transport and Its Application for Improving Hydraulic Fracturing Performance

A fault location method based on polarization analysis for coal mine

Experimental Study on the Influence of Hydrochemical Properties on the Migration of Coal Fines Containing Kaolinite in Propped Fractures

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Product

Resources

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Permeability Enhancement via Acetic Acid (CH₃COOH) Acidizing in Coals Containing Fracture-Filling Calcite