Hydraulic fracture propagation in soft coal composite reservoirs: Mechanical responses and energy dissipation mechanisms

Aitao Zhou; Yizheng He; Kai Wang; Bo Li; Yida Wang; Yuexin Yang

doi:10.1016/j.ijmst.2025.02.008

Int J Min Sci Technol ›› 2025, Vol. 35 ›› Issue (4) : 573 -588. DOI: 10.1016/j.ijmst.2025.02.008

Hydraulic fracture propagation in soft coal composite reservoirs: Mechanical responses and energy dissipation mechanisms

Aitao Zhou ^a^,^b
, Yizheng He ^a
, Kai Wang ^a^,^b^,^*
, Bo Li ^c^,^d^,^*
, Yida Wang ^a
, Yuexin Yang ^a

Author information +

History +

PDF (20789KB)

Abstract

The hydraulic fractures induced in soft coal composite reservoirs have complex extension and energy evolution characteristics. In this study, the mechanism whereby gas outbursts can be eliminated by hydraulic fracturing was revealed. The combined fracturing process of a coal seam and its roof under different in situ stress and fracture spacing conditions was analysed through true triaxial physical tests and numerical simulations. The results showed that the pre-fracturing of the roof had a pressure relief effect on the coal seam, and the secondary pressure relief of the coal seam could be completed at a lower fracture initiation pressure. To ensure the continued presence of the stress shadow effect in actual projects, the fracture spacing should be maintained within the critical range influencing the fracture extension. If the vertical stress is high, a call on increasing the fracture spacing can be taken; otherwise, it must be reduced. In the early phase of fracturing, energy is mostly concentrated at the tip and surface of the fracture; however, the proportion of surface energy for subsequent fracturing is gradually reduced, and the energy is mostly used to open the formation and work on the surrounding matrix. Hydraulic fracturing creates new fractures to interconnect originally heterogeneously distributed gas zones, enabling the entire coal seam to first establish interconnected pressure equilibration, then undergo gradient-controlled depressurization. Hydraulic fracturing can homogenize the stress field and gas pressure field in the original coal seam via communication pressure equalization and reduction decompression, reduce the elastic and extension energies, increase the minimum failure energy required for instability; and realize the elimination of gas outbursts. Our findings provide some theoretical support for the efficient development of coalbed methane and the prevention and control of dynamic gas disasters in coal mines.

Keywords

Coal-rock complex / Soft coal seams / Hydraulic fracturing / Energy evolution / Eliminating gas outburst

Cite this article

Download citation ▾

Aitao Zhou, Yizheng He, Kai Wang, Bo Li, Yida Wang, Yuexin Yang. Hydraulic fracture propagation in soft coal composite reservoirs: Mechanical responses and energy dissipation mechanisms. Int J Min Sci Technol, 2025, 35(4): 573-588 DOI:10.1016/j.ijmst.2025.02.008

登录浏览全文

4963

注册一个新账户忘记密码

Acknowledgments

This research is financially supported by the National Key R&D Program (Nos. 2023YFC3009000 and 2023YFC3006804) and the National Natural Science Foundation of China (Nos. 52130409, 52121003, 51874314, and 52274190).

References

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

[1]	Yuan L. Strategic thinking of simultaneous exploitation of coal and gas in deep mining. J China Coal Soc 2016; 41(1):1-6. in Chinese.

[2]	He MC, Wang Q. Rock dynamics in deep mining. Int J Min Sci Technol 2023; 33 (9):1065-82.

[3]	Yang F, Ge ZL, Zheng JL, Tian ZY. Viscoelastic surfactant fracturing fluid for underground hydraulic fracturing in soft coal seams. J Petrol Sci Eng 2018;169:646-53.

[4]	Xie HP, Lu J, Li CB, Li MH, Gao MZ. Experimental study on the mechanical and failure behaviors of deep rock subjected to true triaxial stress: A review. Int J Min Sci Technol 2022; 32(5):915-50.

[5]	Panaghi K, Golshani A, Sato M, Takemura T, Takahashi M. Crack tensor-based evaluation of Inada granite behavior due to damage under true-triaxial testing condition. Int J Rock Mech Min Sci 2018;106:30-40.

[6]	Guha Roy D, Singh TN, Kodikara J, Das R. Effect of water saturation on the fracture and mechanical properties of sedimentary rocks. Rock Mech Rock Eng 2017; 50(10):2585-600.

[7]	Zhu CQ, Wang L, Zhang Y, Shang RH, Wang AC. Effect of moisture content on wave velocity and failure characteristics of soft coal. Rock Soil Mech 2024; 45 (11):3271-85. in Chinese.

[8]	Xu ZJ, Li C, Cao Y, Tai LH, Han J. A case study on new high-strength temporary support technology of extremely soft coal seam roadway. Sci Rep 2023;13:21333.

[9]	Li DQ. A new technology for the drilling of long boreholes for gas drainage in a soft coal seam. J Petrol Sci Eng 2016;137:107-12.

[10]	Sun SQ, Zhang Q, Yan ZM, Zhang J, Wang YW, Zheng KG. Practice of permeability enhancement through overall hydraulic fracturing of long hole in outburst-prone soft crushed coal seam with low permeability. J China Coal Soc 2017; 42(9):2337-44. in Chinese.

[11]	Zhang CH, Zhang YZ, Li JT, Li TD. Comparison analysis on permeability improved effect of single and multi-section hydraulic fracturing in deep depth seam. Coal Sci Technol 2017; 45(6):50-4.

[12]	Yang JZ, Zheng KG, Wang ZR, Pang NY. Technology of weakening and dangerbreaking dynamic disasters by hard roof. J China Coal Soc 2020; 45 (10):3371-9. in Chinese.

[13]	Zheng KG, Yang JZ, Li BG, Li YJ, Dai N, Yang H. Collapse filling-based technology of weakening and danger-solving by staged fracturing in hard roof. Coal Geol Explor 2021; 49(5):77-87. in Chinese.

[14]	Ren M, Yang B, Yang D, Liu Y, Zhang H, Zhang MY, Zhang Y. Optimizing the preparation of multi-colored dye-tracer proppants: A potential approach for quantitative localization and volume assessment of proppant flowback in multistage fractured horizontal wells. Geoenergy Sci Eng 2024;240:213053.

[15]	Cao HX, Xie HD, Yang H, Wang FG, Yan XY, Zhang J. Mine earthquake control through weakening the low key stratum in Dongtan Coal Mine. Coal Eng 2021; 53(4):71-5. in Chinese.

[16]	Yao NP, Zhang J, Zhang GL, Du LM, Zhang XL, Song B, Ren HH. System of gas drainage technology of comb-like directional drilling in Jincheng Mining Area. Coal Sci Technol 2015; 43(2):88-91. in Chinese.

[17]	Zheng KG. Permeability improving technology by sectional hydraulic fracturing for comb-like long drilling in floor of crushed and soft coal seam with low permeability. J Min Saf Eng 2020; 37(2):272-81. in Chinese.

[18]	Chen DD, Wang JL, Jia BY, Xi J. High-efficiency regional gas drainage model after hydraulic fracturing of comb-shaped long boreholes in the roof of broken soft and low permeability coal seam. Coal Geol Explor 2022; 50(8):29-36. in Chinese.

[19]	Mou QB, Yan ZM, Zhang J. High efficiency gas drainage technology of hydraulic fracturing with directional long drilling in underground coal mine. Coal Sci Technol 2020; 48(7):296-303. in Chinese.

[20]	Li B, He YZ, Shi Z, Jian W, Wang NN, Zhang YP. Mutual feedback and fracturing effect of hydraulic fractures in composite coal-rock reservoirs under different fracturing layer sequence conditions. Int J Rock Mech Min Sci 2024;184:105968.

[21]	Yoon JS, Zimmermann G, Zang A. Numerical investigation on stress shadowing in fluid injection-induced fracture propagation in naturally fractured geothermal reservoirs. Rock Mech Rock Eng 2015; 48(4):1439-54.

[22]	Zeng QD, Yao J. Numerical simulation of fracture network generation in naturally fractured reservoirs. J Nat Gas Sci Eng 2016;30:430-43.

[23]	Zhou J, Zeng YJ, Jiang TX, Zhang BP. Laboratory scale research on the impact of stress shadow and natural fractures on fracture geometry during horizontal multi-staged fracturing in shale. Int J Rock Mech Min Sci 2018;107:282-7.

[24]	Taghichian A, Zaman M, Devegowda D. Stress shadow size and aperture of hydraulic fractures in unconventional shales. J Petrol Sci Eng 2014;124:209-21.

[25]	Han WG, Cui ZD, Zhang JY. Fracture path interaction of two adjacent perforations subjected to different injection rate increments. Comput Geotech 2020;122:103500.

[26]	Hu QT, Liu L, Li QG, Wu YQ, Wang XG, Jiang ZZ, Yan FZ, Xu YC, Wu XB. Experimental investigation on crack competitive extension during hydraulic fracturing in coal measures strata. Fuel 2020;265:117003.

[27]	Warpinski NR, Teufel LW. Influence of geologic discontinuities on hydraulic fracture propagation (including associated papers 17011 and 17074). J Petrol Technol 1987; 39(2):209-20.

[28]	Bi ZH, Wang L, Yang HZ, Guo YT, Chang X, Zhou J. Experimental study on the initiation and propagation of multi-cluster hydraulic fractures within one stage in horizontal wells. Energies 2021; 14(17):5357.

[29]	Yang L, Wu S, Gao K, Shen LM. Simultaneous propagation of hydraulic fractures from multiple perforation clusters in layered tight reservoirs: Non-planar three-dimensional modelling. Energy 2022;254:124483.

[30]	Zhao HP, Liu RJ, Hu JH, Zhang Y. A comprehensive model to evaluate hydraulic fracture spacing coupling with fluid transport and stress shadow in tight oil reservoirs. Transp Porous Medium 2023; 149(1):205-28.

[31]	Wang K, Zhang X, Guo HJ, Fu Q, Wang DK, Zhang H, Lu FC. Experimental study on hydraulic fracturing of laminated sandstone combined with industrial CT and L-NMR. Geofluids 2022; 2022(1):5716346.

[32]	Li B, He YZ, Li L, Zhang JX, Shi Z, Zhang YP. Damage evolution of rock containing prefabricated cracks based on infrared radiation and energy dissipation. Theor Appl Fract Mech 2023;125:103853.

[33]	Haddad M, Sepehrnoori K. XFEM-based CZM for the simulation of 3D multiplecluster hydraulic fracturing in quasi-brittle shale formations. Rock Mech Rock Eng 2016; 49(12):4731-48.

[34]	Tan P, Jin Y, Pang HW. Hydraulic fracture vertical propagation behavior in transversely isotropic layered shale formation with transition zone using XFEM-based CZM method. Eng Fract Mech 2021;248:107707.

[35]	Guo JC, Luo B, Lu C, Lai J, Ren JC. Numerical investigation of hydraulic fracture propagation in a layered reservoir using the cohesive zone method. Eng Fract Mech 2017;186:195-207.

[36]	Huang LS, Li B, Wu B, Li C, Wang JX, Cai HW. Study on the extension mechanism of hydraulic fractures in bedding coal. Theor Appl Fract Mech 2024;131:104431.

[37]	Hou B, Cui Z. Vertical fracture propagation behavior upon supercritical carbon dioxide fracturing of multiple layers. Eng Fract Mech 2023;277:108913.

[38]	Wang B, Zhou FJ, Zou YS, Liang TB, Wang DB, Xue YP, Gao LY. Quantitative investigation of fracture interaction by evaluating fracture curvature during temporarily plugging staged fracturing. J Petrol Sci Eng 2019;172:559-71.

[39]	Wang B, Zhou FJ, Wang DB, Liang TB, Yuan LS, Hu J. Numerical simulation on near-wellbore temporary plugging and diverting during refracturing using XFEM-Based CZM. J Nat Gas Sci Eng 2018;55:368-81.

[40]	Yan DD, Zhao LX, Song XH, Tang JZ, Zhang FS. Fracability evaluation model for unconventional reservoirs: From the perspective of hydraulic fracturing performance. Int J Rock Mech Min Sci 2024;183:105912.

[41]	Feng RH, Zhang YH, Rezagholilou A, Roshan H, Sarmadivaleh M. Brittleness index: From conventional to hydraulic fracturing energy model. Rock Mech Rock Eng 2020; 53(2):739-53.

[42]	Abou-Sayed AS, Brechtel CE, Clifton RJ. In situ stress determination by hydrofracturing: A fracture mechanics approach. J Geophys Res Solid Earth 1978; 83(B6):2851-62.

[43]	Shu LY, Wang K, Qi QX, Fan SW, Zhang L, Fan XS. Key structural body theory of coal and gas outburst. Chin J Rock Mech Eng 2017; 36(2):347-56.

[44]	Li CW, Xie BJ, Cao JL, Wang TT, Wang XY. The energy evaluation model of coal and gas outburst intensity. J China Coal Soc 2012; 37(9):1547-52. in Chinese.

[45]	Wei FQ, Shi GS, Zhang TG. Study on coal and gas outburst prediction indexes based on gas expansion energy. J China Coal Soc 2010;35:96-9. in Chinese.