Hydraulic fracture prediction theory based on the minimumstrain energy density criterion
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摘要: 建立了考慮裂紋尖端非奇異項T應力的最小應變能密度因子斷裂準則, 研究了不同裂紋類型條件下T應力和泊松比對起裂角的影響, 結果表明裂紋起裂角不僅與奇異項應力強度因子有關, 而且還需要考慮非奇異項T應力和泊松比的影響作用.同時計算了含井筒對稱雙裂紋水力壓裂模型的起裂角和臨界水壓, 表明依據本文斷裂準則計算得到理論解與實驗結果吻合良好.在此基礎上, 利用該準則從理論上分析了臨界裂紋區尺寸、T應力、比奧系數、側壓系數、泊松比等因素對水力壓裂裂紋起裂特性的影響.參數分析表明: 臨界裂紋區尺寸、T應力和側壓系數對臨界水壓和臨界起裂角有顯著影響.臨界水壓隨著泊松比增大而減小, 而臨界起裂角呈現相反變化趨勢.比奧系數對臨界起裂角沒有影響, 但是在高水壓條件下對起裂角具有顯著影響.Abstract: Hydraulic fracturing is a promising technique used in oil and gas reservoirs, enhanced geothermal systems, and coal gas production.Although its use is widespread, many aspects of hydraulic fracturing are still not well understood and need to be further investigated to achieve increases in oil and gas production while mitigating the adverse aspects of hydraulic fracturing.Understanding how hydraulic pressure extends preexisting fractures and forms a complex fracture network is essential for the design and treatment of hydraulic fracturing.Critical water pressure and fracture initiation angle are two important parameters involved in the hydraulic fracture propagation process and production from a well.In the present study, a minimum strain energy density criterion, which considers the effects of T-stress and Poisson's ratio, was proposed to analyze fracture initiation during hydraulic fracturing.The fracture initiation angle for different crack types was investigated using the proposed theoretical method, and the results indicate that the fracture initiation angle is not only related to the stress intensity factor but also affected by the T-stress and Poisson's ratio.The critical water pressure and critical initiation angle for two symmetric radial cracks emanating from a pressurized borehole were investigated, and the theoretical results were consistent with the experimental results.Through the proposed theoretical method, the influence of T-stress, radius of the fracture process zone, Biot's coefficient, lateral pressure coefficient and Poisson's ratio on the hydraulic fracturing behavior was analyzed.Parameter analysis indicates that the radius of the fracture process zone, T-stress, and lateral pressure coefficient play an important role in the critical initiation angle and critical water pressure.The critical water pressure increases with the decrement of Poisson's ratio, whereas the critical initiation angle shows the opposite trend.Biot's coefficient has no effect on the critical initiation angle but has a significant influence on the fracture initiation angle under high water pressure.The theoretical model enables a comprehensive understanding of the characteristics of hydraulic fracturing under complex loading conditions.The results also provided a basis for quantitative investigations of the engineering design of hydraulic fracturing treatments.
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圖 1 純I型裂紋起裂角與泊松比υ和T應力的關系
Figure 1. Relationship between Poisson's ratio, T-stress, and fracture initiation angle under pure Mode I
圖 2 純II型裂紋起裂角θ0與泊松比υ和T應力的關系
Figure 2. Relationship between Poisson's ratio, T-stress, and fracture initiation angle under pure Mode II
圖 5 起裂角θ0實驗數據與理論計算(有無T應力) 的對比. (a) σH /σh = 4; (b) σH /σh = 6
Figure 5. Experimental and theoretical results (with or without T-stress) of the fracture initiation angle: (a) σH /σh = 4; (b) σH /σh = 6
圖 6 臨界水壓Pc和臨界起裂角θ0實驗數據與理論計算對比. (a) σH /σh = 4; (b) σH /σh = 6; (c) σH /σh = 4; (d) σH /σh = 6
Figure 6. Experimental and theoretical results of the critical water pressure and fracture initiation angle: (a) σH /σh = 4; (b) σH /σh = 6; (c) σH /σh = 4; (d) σH /σh = 6
圖 7 T應力的影響.(a) 臨界水壓Pc; (b)臨界起裂角θ0
Figure 7. Effect of T-stress: (a) critical water pressure Pc; (b) critical initiation angle θ0
圖 8 比奧系數的影響. (a) 臨界水壓Pc; (b) 臨界起裂角θ0
Figure 8. Effect of Biot's coefficient: (a) critical water pressure Pc; (b) critical initiation angle θ0
圖 9 側壓系數k的影響. (a) 臨界水壓Pc; (b) 臨界起裂角θ0
Figure 9. Effect of lateral pressure coefficient : (a) critical water pressure Pc; (b) critical initiation angle θ0
圖 10 泊松比υ的影響. (a) 臨界水壓Pc; (b) 臨界起裂角θ0
Figure 10. Effect of Poisson's ratio: (a) critical water pressure Pc; (b) critical initiation angle θ0
圖 11 不同泊松比υ條件下裂紋尖端最大主應力
Figure 11. Maximum principal stresses of the crack tip under different Poisson's ratios
圖 12 高注水壓力對起裂角θ0的影響
Figure 12. Effect of high injected water pressure on the fracture initiation angle
圖 13 不同因素對起裂角θ0的影響. (a) 側壓系數; (b) 比奧系數; (c) 泊松比
Figure 13. Effect of different factors on the fracture initiation angle: (a) lateral pressure coefficient; (b) Biot's coefficient; (c) Poisson's ratio
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參考文獻
[1] Chen M, Jin Y, Zhang G Q. Petroleum Engineering Rock Mechanics. Beijing: Science Press, 2008陳勉, 金衍, 張廣清. 石油工程巖石力學. 北京: 科學出版社, 2008 [2] Liu J Z, Liu X G, Zhang X, et al. The great scale rock experiment simulating hydraulic fracturing. Acta Geophys Sin, 1994, 37 (Suppl 1): 161 https://www.cnki.com.cn/Article/CJFDTOTAL-DQWX4S2.016.htm劉建中, 劉翔鶚, 張雪, 等. 大尺度水壓致裂模擬實驗. 地球物理學報, 1994, 37(增刊1): 161 https://www.cnki.com.cn/Article/CJFDTOTAL-DQWX4S2.016.htm [3] Jiang H, Chen M, Zhang G Q, et al. Impart of oriented perforation on hydraulic fracture initiation and propagation. Chin J Rock Mech Eng, 2009, 28(7): 1321 doi: 10.3321/j.issn:1000-6915.2009.07.004姜滸, 陳勉, 張廣清, 等. 定向射孔對水力裂縫起裂與延伸的影響. 巖石力學與工程學報, 2009, 28(7): 1321 doi: 10.3321/j.issn:1000-6915.2009.07.004 [4] Wang D, Chen M, Jon Y, et al.Experimental study of fracture initiation and propagation from a wellbore//49th US Rock Mechanics/Geomechanics Symposium.San Francisco, 2015: ARMA- 2015-068 [5] Li W, Li L C, Tang C A. Numerical simulation research on mechanism of induced stress perturbation between parallel fractures in horizontal wells. Nat Gas Geosci, 2016, 27(11): 2043 doi: 10.11764/j.issn.1672-1926.2016.11.2043李旺, 李連崇, 唐春安. 水平井平行裂縫間誘導應力干擾機制的數值模擬研究. 天然氣地球科學, 2016, 27(11): 2043 doi: 10.11764/j.issn.1672-1926.2016.11.2043 [6] Liu C, Shi F, Lu D T, et al. Numerical simulation of simultaneous multiple fractures initiation in unconventional reservoirs through injection control of horizontal well. J Petrol Sci Eng, 2017, 159: 603 doi: 10.1016/j.petrol.2017.09.064 [7] Shi F, Wang X L, Liu C, et al. An XFEM-based method with reduction technique for modeling hydraulic fracture propagation in formations containing frictional natural fractures. Eng Fract Mech, 2017, 173: 64 doi: 10.1016/j.engfracmech.2017.01.025 [8] Nadimi S, Miscovic I, McLennan J. A 3D peridynamic simulation of hydraulic fracture process in a heterogeneous medium. J Petrol Sci Eng, 2016, 145: 444 doi: 10.1016/j.petrol.2016.05.032 [9] Lian Z L, Zhang J, Wang X X, et al. Simulation study of characteristics of hydraulic fracturing propagation. Rock Soil Mech, 2009, 30(1): 169 doi: 10.3969/j.issn.1000-7598.2009.01.029連志龍, 張勁, 王秀喜, 等. 水力壓裂擴展特性的數值模擬研究. 巖土力學, 2009, 30(1): 169 doi: 10.3969/j.issn.1000-7598.2009.01.029 [10] Wang X L, Shi F, Liu H, et al. Numerical simulation of hydraulic fracturing in orthotropic formation based on the extended finite element method. J Nat Gas Sci Eng, 2016, 33: 56 doi: 10.1016/j.jngse.2016.05.001 [11] Hosseini S M.On the linear elastic fracture mechanics application in Barnett shale hydraulic fracturing//47th US Rock Me chanics /Geomechanics Symposium.San Francisco, 2013: AR- MA-2013-644 [12] Pu C Z, Cao P, Zhang C Y, et al. Fracture failure mechanism of rock with closed crack and judging criterion of seepage pressure under biaxial compression. Rock Soil Mech, 2015, 36(1): 56 https://www.cnki.com.cn/Article/CJFDTOTAL-YTLX201501007.htm蒲成志, 曹平, 張春陽, 等. 雙向壓縮條件下閉合裂隙巖體斷裂破壞機制及滲透壓環境判定準則. 巖土力學, 2015, 36 (1): 56 https://www.cnki.com.cn/Article/CJFDTOTAL-YTLX201501007.htm [13] Li X B, He X Q, Chen H J. Crack initiation characteristics of opening-mode crack embedded in rock-like material under seepage pressure. Chin J Rock Mech Eng, 2012, 31(7): 1317 doi: 10.3969/j.issn.1000-6915.2012.07.002李夕兵, 賀顯群, 陳紅江. 滲透水壓作用下類巖石材料張開型裂紋啟裂特性研究. 巖石力學與工程學報, 2012, 31 (7): 1317 doi: 10.3969/j.issn.1000-6915.2012.07.002 [14] Tang S B, Dong Z, Huang R Q. Determination of T-stress using finite element analysis. Sci China Technol Sci, 2017, 60 (8) : 1211 doi: 10.1007/s11431-016-0835-2 [15] Li S Y, He T M, Yin X C. Introduction of Rock Fracture Mechanics. Hefei: University of Science and Technology of China Press, 2010李世愚, 和泰名, 尹祥礎. 巖石斷裂力學導論. 合肥: 中國科學技術大學出版社, 2010 [16] Jin X C.An Integrated Geomechanics and Petrophysics Study of Hydraulic Fracturing in Naturally Fractured Reservoirs [Dissertation].Norman: University of Oklahoma, 2014 [17] Tang S B. The effect of T-stress on the fracture of brittle rock under compression. Int J Rock Mech Min Sci, 2015, 79: 86 doi: 10.1016/j.ijrmms.2015.06.009 [18] Seweryn A. A non-local stress and strain energy release rate mixed mode fracture initiation and propagation criteria. Eng Fract Mech, 1998, 59(6): 737 doi: 10.1016/S0013-7944(97)00175-6 [19] Wei Y J. An extended strain energy density failure criterion by differentiating volumetric and distortional deformation. Int J Solids Struct, 2012, 49(9): 1117 doi: 10.1016/j.ijsolstr.2012.01.015 [20] Ayatollahi M R, Moghaddam M R, Razavi S M J, et al. Geometry effects on fracture trajectory of PMMA samples under pure mode-I loading. Eng Fract Mech, 2016, 163: 449 doi: 10.1016/j.engfracmech.2016.05.014 [21] Ayatollahi M R, Moghaddam M R, Berto F. A generalized strain energy density criterion for mixed mode fracture analysis in brittle and quasi-brittle materials. Theor Appl Fract Mech, 2015, 79: 70 doi: 10.1016/j.tafmec.2015.09.004 [22] Williams M L. On the stress distribution at the base of a stationary crack. J Appl Mech, 1957, 24: 109 doi: 10.1115/1.4011454 [23] Khan S M A, Khraisheh M K. Analysis of mixed mode crack initiation angles under various loading conditions. Eng Fract Mech, 2000, 67(5): 397 doi: 10.1016/S0013-7944(00)00068-0 [24] Smith D J, Ayatollahi M R, Pavier M J. On the consequences of T-stress in elastic brittle fracture. Proc R Soc London A, 2006, 462(2072): 2415 http://adsabs.harvard.edu/abs/2006RSPSA.462.2415S [25] Sih G C. Strain-energy-density factor applied to mixed mode crack problems. Int J Fract, 1974, 10(3): 305 doi: 10.1007/BF00035493 [26] ANSYS Inc.ANSYS Mechanical Theory Reference:Release 15.0.Canonsburg,2014 [27] Guo F, Morgenstern N R, Scott J D.Interpretation of hydraulic fracturing breakdown pressure//International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts.Pergamon, 1993: 617 [28] Bruno M S, Nakagawa F M.Pore pressure influence on tensile fracture propagation in sedimentary rock//International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts.Pergamon, 1991: 261 [29] Hossain M M, Rahman M K, Rahman S S. Hydraulic fracture initiation and propagation: roles of wellbore trajectory, perforation and stress regimes. J Petrol Sci Eng, 2000, 27(3-4): 129 doi: 10.1016/S0920-4105(00)00056-5 [30] Ikeda R, Tsukahara H.Hydraulic fracturing technique: pore pressure effect and stress heterogeneity//International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts.Pergamon, 1989: 471 [31] Haimson B, Fairhurst C. Hydraulic fracturing in porous-permeable materials. J Petrol Technol, 1969, 21(7): SPE-2354-PA http://www.researchgate.net/publication/250086937_Hydraulic_Fracturing_in_Porous-Permeable_Materials [32] da Silva B G, Einstein H H. Finite element study of fracture initiation in flaws subject to internal fluid pressure and vertical stress. Int J Solids Struct, 2014, 51(23-24): 4122 doi: 10.1016/j.ijsolstr.2014.08.006 -
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