Numerical modelling of fracturing effect stimulated by pulsating hydraulic fracturing in coal seam gas reservoir

Source-pathway-receptor analyses involving solute migration pathways through soil and shallow groundwater are typically undertaken to assess how people and the environment could come into contact with chemicals associated with coal seam gas operations. For the potential short-term and long-term release of coal seam gas fluids from storage ponds, solute concentration and dilution factors have been calculated using a water flow and solute transport modelling framework for an unsaturated zone-shallow groundwater system. Uncertainty about dilution factors was quantified for a range of system parameters: (i) leakage rates from storage ponds combined with recharge rates, (ii) a broad combination of soil and groundwater properties, and (iii) a series of increasing travel distances through soil and groundwater. Calculated dilution factors in the soil increased from sand to loam soil and increased with an increasing recharge rate, while dilution decreased for a decreasing leak rate and leak duration. In groundwater, dilution factors increase with increasing aquifer hydraulic conductivity and riverbed conductance. For a hypothetical leak duration of three years, the combined soil and groundwater dilution factors are larger than 6980 for more than 99.97% of bores that are likely to be farther than 100 m from the source. Dilution factors were more sensitive to uncertainty in leak rates than recharge rates. Based on this dilution factor, a comparison of groundwater predicted environmental concentrations and predicted no-effect concentrations for a subset of hydraulic fracturing chemicals used in Australia revealed that for all but two of the evaluated chemicals the estimated groundwater concentration (for a hypothetical water bore at 100 m from the solute source) is smaller than the no-effect concentration for the protection of aquatic ecosystems.

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Stress Distribution and Gas Concentration Evolution during Protective Coal Seam Mining

Advances in Civil Engineering ◽

10.1155/2021/6644142 ◽

2021 ◽

Vol 2021 ◽

pp. 1-12

Author(s):

Xingang Niu ◽

Biming Shi ◽

Zhigang Zhang ◽

Yongjiang Zhang

Keyword(s):

Numerical Modelling ◽

Coal Seam ◽

Mining Method ◽

Coal Seam Gas ◽

Gas Concentration ◽

Induced Stress ◽

Complete Extraction ◽

Stress Zone ◽

Seam Mining ◽

Concentration Evolution

Coal and gas burst is one of the significant and catastrophic hazards in underground longwall operations. To date, the protective coal seam mining has been recognized as the most effective mining method for minimizing or even avoiding the effect of the coal and gas burst. In this paper, numerical modelling and field test were carried out for the longwall operation in Qidong Coal Mine in order to investigate the induced stress and coal seam gas drainage performance in the protected coal seam after the complete extraction of the protective coal seam. It was found that four stress zones can be classified in the protected coal seam being the original stress zone, stress concentration zone, stress relief zone, and recompaction zone. In addition, the monitoring data of gas concentration and volume change in the field agree well with the numerical modelling results.

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Quantifying the Influence of Three Dimensionality on Hydraulic Fracturing in Coal Seam Gas Wells

Proceedings of the SPE/AAPG/SEG Asia Pacific Unconventional Resources Technology Conference ◽

10.15530/ap-urtec-2019-198203 ◽

2019 ◽

Author(s):

Christopher R. Leonardi ◽

Thomas Flottmann ◽

Vibhas J. Pandey ◽

Raymond J. Johnson Jr.

Keyword(s):

Coal Seam ◽

Hydraulic Fracturing ◽

Gas Wells ◽

Coal Seam Gas

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Technology Update: Characterizing a Coal-Seam Gas Reservoir by Interpreting Permanent DTS Data

Journal of Petroleum Technology ◽

10.2118/0718-0018-jpt ◽

2018 ◽

Vol 70 (07) ◽

pp. 18-20

Author(s):

Iko Oguche ◽

Michael Konopczynski

Keyword(s):

Coal Seam ◽

Coal Seam Gas ◽

Gas Reservoir

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A semi-analytical model for the transient pressure behaviors of a multiple fractured well in a coal seam gas reservoir

Journal of Petroleum Science and Engineering ◽

10.1016/j.petrol.2020.108159 ◽

2021 ◽

Vol 198 ◽

pp. 108159

Author(s):

Haitao Wang ◽

Zuhao Kou ◽

Jingjing Guo ◽

Zhuoting Chen

Keyword(s):

Coal Seam ◽

Analytical Model ◽

Transient Pressure ◽

Coal Seam Gas ◽

Gas Reservoir ◽

Fractured Well

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In vitro cytotoxicity assessment of a hydraulic fracturing fluid

Environmental Chemistry ◽

10.1071/en14010 ◽

2015 ◽

Vol 12 (3) ◽

pp. 286 ◽

Cited By ~ 5

Author(s):

Madeleine E. Payne ◽

Heather F. Chapman ◽

Janet Cumming ◽

Frederic D. L. Leusch

Keyword(s):

Coal Seam ◽

Hydraulic Fracturing ◽

Human Health ◽

Produced Water ◽

Coal Seam Gas ◽

Fracturing Fluid ◽

Human Health Risks ◽

Fracturing Fluids ◽

Hydraulic Fracturing Fluid

Environmental context Hydraulic fracturing fluids, used in large volumes by the coal seam gas mining industry, are potentially present in the environment either in underground formations or in mine wastewater (produced water). Previous studies of the human health and environmental effects of this practice have been limited because they use only desktop methods and have not considered combined mixture toxicity. We use a novel in vitro method for toxicity assessment, and describe the toxicity of a hydraulic fracturing fluid on a human gastrointestinal cell line. Abstract Hydraulic fracturing fluids are chemical mixtures used to enhance oil and gas extraction. There are concerns that fracturing fluids are hazardous and that their release into the environment – by direct injection to coal and shale formations or as residue in produced water – may have effects on ecosystems, water quality and public health. This study aimed to characterise the acute cytotoxicity of a hydraulic fracturing fluid using a human gastrointestinal cell line and, using this data, contribute to the understanding of potential human health risks posed by coal seam gas (CSG) extraction in Queensland, Australia. Previous published research on the health effects of hydraulic fracturing fluids has been limited to desktop studies of individual chemicals. As such, this study is one of the first attempts to characterise the toxicity of a hydraulic fracturing mixture using laboratory methods. The fracturing fluid was determined to be cytotoxic, with half maximal inhibitory concentrations (IC50) values across mixture variations ranging between 25 and 51mM. When used by industry, these fracturing fluids would be at concentrations of over 200mM before injection into the coal seam. A 5-fold dilution would be sufficient to reduce the toxicity of the fluids to below the detection limit of the assay. It is unlikely that human exposure would occur at these high (‘before use’) concentrations and likely that the fluids would be diluted during use. Thus, it can be inferred that the level of acute risk to human health associated with the use of these fracturing fluids is low. However, a thorough exposure assessment and additional chronic and targeted toxicity assessments are required to conclusively determine human health risks.

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