Evolution law of pulsating seepage and thermal deformation by injecting high-temperature steam into coal for thermal coalbed methane recovery

Zhiqiang Li; Junliang Li; Jinsheng Chen; Ali Karrech; Ningchao Zhang; Ju Chang; Kaiqi Jin; Yangyang Yu; Hongbin Wang; Aijie Wang

doi:10.1002/dug2.12087

Deep Underground Science and Engineering ›› 2025, Vol. 4 ›› Issue (1) :119 -131. DOI: 10.1002/dug2.12087

RESEARCH ARTICLE

Evolution law of pulsating seepage and thermal deformation by injecting high-temperature steam into coal for thermal coalbed methane recovery

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Abstract

Chinese coal reservoirs are characterized by low pressure and low permeability, which need to be enhanced so as to increase production. However, conventional methods for permeability enhancement can only increase the permeability in fractures, but not the ultra-low permeability in coal matrices. Attempts to enhance such impermeable structures lead to rapid attenuation of gas production, especially in the late stage of gas extraction. Thermal stimulation by injecting high-temperature steam is a promising method to increase gas production. The critical scientific challenges that still hinder its widespread application are related to the evolution law of permeability of high-temperature steam in coal and the thermal deformation of coal. In this study, an experimental approach is developed to explore the high-temperature steam seepage coupled with the thermal deformation in coal under triaxial stress. The tests were conducted using cylindrical coal specimens of ϕ50 mm × 100 mm. The permeability and thermal strain in coal were investigated when high-temperature steam was injected at 151.11, 183.20, 213.65, and 239.76℃. The experimental results reveal for the first time that as the amount of injected fluid increases, the steam permeability shows periodic pulsation changes. This paper introduces and explains the main traits of this discovery that may shed more light on the seepage phenomenon. When the injected steam temperature increases, the amplitude of pulsating permeability decreases, whereas the frequency increases; meanwhile, the period becomes shorter, the pulsation peak appears earlier, and the stabilization time becomes longer. The average peak permeability shows a “U-shaped” trend, decreasing first and then increasing as the steam temperature increases. Meanwhile, with the extension of steam injection time, the axial, radial, and volumetric strains of coal show a stage-wise expansion characteristic at different temperatures of steam injection, except for the radial strains at 151.11℃. A two-phase flow theory of gas-liquid is adopted to elucidate the mechanism of pulsating seepage of steam. Moreover, the influencing mechanism of inward and outward thermal expansion on the permeability of coal is interpreted. The results presented in this paper provide new insight into the feasibility of thermal gas recovery by steam injection.

Keywords

coalbed methane / permeability / pulsation / steam / thermal deformation / two-phase flow

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Zhiqiang Li, Junliang Li, Jinsheng Chen, Ali Karrech, Ningchao Zhang, Ju Chang, Kaiqi Jin, Yangyang Yu, Hongbin Wang, Aijie Wang. Evolution law of pulsating seepage and thermal deformation by injecting high-temperature steam into coal for thermal coalbed methane recovery. Deep Underground Science and Engineering, 2025, 4(1): 119-131 DOI:10.1002/dug2.12087

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Cheng H, Zhang N, Yang Y, Peng W, Chen H. A study on the mechanical mechanism of injection heat to increase production of gas in low-permeability coal seam. Energies. 2019; 12: 2332.

[2]	Fabre J, Peresson LL, Corteville J, Odello R, Bourgeois T. Severe slugging in pipeline/riser systems. SPE Prod Eng. 1990; 5: 299-305.

[3]	Fang HH, Sang SX, Liu SQ. Numerical simulation of enhancing coalbed methane recovery by injecting CO₂ with heat injection. Pet Sci. 2019; 16: 32-43.

[4]	Fang X, Wu C, Zhang H, et al. Stress distribution properties and deformation-fracture mechanisms in hydraulic fracturing of coal. Fuel. 2023; 351:129049.

[5]	Hu L, Feng Z, Zhou D, et al. Numerical simulation study and engineering practice of in-situ heat injection mining of coalbed methane. J China Coal Soc. 2023; 48(12): 4473-4486.

[6]	Hu L, Feng Z, Zhou D, Wang X. Experimental research and industrial application of heat injection-enhanced coalbed methane extraction. Coal Sci Technol. 2022; 50(12): 194-205.

[7]	Hu L, Feng Z, Zhou D, Wang X. Mechanisms and field application of in situ heat injection-enhanced gas drainage. Energy. 2023; 284:128729.

[8]	Jansen FE, Shoham O, Taitel Y. The elimination of severe slugging—experiments and modeling. Int J Multiphase Flow. 1996; 22: 1055-1072.

[9]	Li W, Yang X, Zhang Y. Experimental study on migration yield law of coal-bed methane under the condition of saturated steam. J China Coal Soci. 2018; 43(5): 1343-1349.

[10]	Li Y, Lin B, Yang K. Evolution law of microscopic pore fractures of coal after hot steam injection. Int J Coal Sci Techn. 2019; 47(12): 102-108.

[11]	Li Y, Zhai C, Sun Y, Xu J, Yu X, Huang T. Characterizing water vapor adsorption on coal by nuclear magnetic resonance: influence of coal pore structure and surface properties. Energy. 2023; 282:128420.

[12]	Li Z, Xian X. An experimental study of the variation of permeability of coal bodies with temperature and stress. J Liaoning Tech Univ (Nat Sci Ed). 2009; 38(4): 156-159.

[13]	Li Z, Xian X, Long Q. Experiment study of coal permeability under different temperature and stress. J China Univ Min Technol. 2009; 38(4): 523-527.

[14]	Liang W, Yan J, Zhang B, Hou D. Review on coal bed methane recovery theory and technology: recent progress and perspectives. Energy Fuels. 2021; 35(6): 4633-4643.

[15]	Liu D, Wang Y, Ni X, et al. Classification of coal structure combinations and their influence on hydraulic fracturing: a case study from the Qinshui basin China. Energies. 2020; 13: 4559.

[16]	Liu J, Kang Y, Chen M, et al. Investigation of enhancing coal permeability with high-temperature treatment. Fuel. 2021; 290:120082.

[17]	Lu Y, Meng Z, Su X, Yu Y. Experimental study of dynamic permeability changes in coals of various ranks during hydraulic fracturing. Nat Resour Res. 2022; 31: 3253-3272.

[18]	Mu Y, Fan Y, Wang J, Fan N. Numerical study on injection of flue gas as a heat carrier into coal reservoir to enhance CBM recovery. J Nat Gas Sci Eng. 2019; 72:103017.

[19]	Niu S, Zhao Y, Hu Y. Experimental investigation of the temperature and pore pressure effect on permeability of lignite under the in situ condition. Transp Porous Media. 2014; 101: 137-148.

[20]	Qu H, Liu J, Chen Z, et al. Complex evolution of coal permeability during CO₂ injection under variable temperatures. Int J Greenhouse Gas Control. 2012; 9: 281-293.

[21]	Salmachi A, Haghighi M. Feasibility study of thermally enhanced gas recovery of coal seam gas reservoirs using geothermal resources. Energy Fuels. 2012; 26: 5048-5059.

[22]	Schmidt Z, Brill JP, Beggs HD. Experimental study of severe slugging in a two-phase-flow pipeline—riser pipe system. Soc Pet Eng J. 1980; 20: 407-414.

[23]	Tang M, Zhang L, Zhen C, Hao D, Zhang Y, Zhang H. Numerical simulation study of coalbed methane injection heat extraction considering vapor phase change. J Min Saf Eng. 2022; 39(2): 370-379.

[24]	Teng T, Wang JG, Gao F, Ju Y. Complex thermal coal-gas interactions in heat injection enhanced CBM recovery. J Nat Gas Sci Eng. 2016; 34: 1174-1190.

[25]	Teng T, Wang W, Zhan P. Evaluation criterion and index for the efficiency of thermal stimulation to dual coal permeability. J Nat Gas Sci Eng. 2019; 68:102899.

[26]	Wang J, Zhao Y, Mao R. Impact of temperature and pressure on the characteristics of two-phase flow in coal. Fuel. 2019; 253: 1325-1332.

[27]	Wang K, Du F, Wang G. Investigation of gas pressure and temperature effects on the permeability and steady-state time of Chinese anthracite coal: an experimental study. J Nat Gas Sci Eng. 2017; 40: 179-188.

[28]	Wang S, Li H, Huang L. Permeability evolution of naturally fractured coal injected with high-temperature nitrogen: experimental observations. Processes. 2021; 9:296.

[29]	Wang S, Zhou F, Kang J, Wang X, Li H, Wang J. A heat transfer model of high-temperature nitrogen injection into a methane drainage borehole. J Nat Gas Sci Eng. 2015; 24: 449-456.

[30]	Yang X. Study on Mechanism of Injection Heat Increasing Production in Coal-bed Gas of Low Permeability Coal Seam. PhD thesis. Liaoning Technical University; 2009.

[31]	Yang X, Bi X, Zhang Y, et al. Numerical simulation of migration and output law of coal-bed methane in heat injection combined well group mining. J Jinlin Univ (Earth Sci Ed). 2019; 49(4): 1100-1108.

[32]	Yang X, Jiang T, Su C, Li W, Zhang Y. Numerical simulation of coalbed methane extraction by pulsation cycle microwave heat injection. J Microwav. 2021; 37(4): 89-94.

[33]	Yang X, Ren C, Zhang Y, Guo R. Numerical simulation of the coupled thermal-fluid-solid mathematical models during extracting methane in low-permeability coal bed by heat injection. J China Coal Soci. 2013; 38(6): 1044-1049.

[34]	Yang X, Zhang Y. Experimental study of effect of temperature on coal gas permeability under gas-solid coupling. J Geomech. 2008; 14(4): 374-380.

[35]	Yang X, Zhang Y. Numerical simulation on flow rules of coal-bed methane by thermal stimulation. J China Univ Min Technol. 2011; 40(1): 89-94.

[36]	Zhou L, Zhou X, Fan C, Bai G. Coal permeability evolution triggered by variable injection parameters during gas mixture enhanced methane recovery. Energy. 2022; 252:124065.

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