Numerical Investigation of Influence of Fluid Rate, Fluid Viscosity, Perforation Angle and NF on HF Re-Orientation in Heterogeneous Rocks Using UDEC T-W Method

DOI HANDLE オープンアクセス
  • Zhang, Shuai
    State Key Laboratory of Coal Resources and Safe Mining, China University of Mining and Technology
  • Xu, Jinhai
    State Key Laboratory of Coal Resources and Safe Mining, China University of Mining and Technology
  • Chen, Liang
    State Key Laboratory of Coal Resources and Safe Mining, China University of Mining and Technology
  • Zhang, Mingwei
    State Key Laboratory for Geomechanics and Deep Underground Engineering, China University of Mining and Technology
  • 笹岡, 孝司
    九州大学大学院工学研究院地球資源システム工学部門
  • 島田, 英樹
    九州大学大学院工学研究院地球資源システム工学部門
  • He, Haiyang
    State Key Laboratory of Coal Resources and Safe Mining, China University of Mining and Technology

説明

Numerical simulation is very useful for understanding the hydraulic fracture (HF) re-orientation mechanism from artificial weaknesses. In this paper, the UDEC T-W (Trigon–Weibull distribution) modeling method is adopted to simulate the hydraulic fracturing process in heterogeneous rocks. First, the reliability of this method is validated against previous laboratory experiments and numerical simulations. Then the effects of fluid rate, fluid viscosity, perforation angle and natural fracture (NF) on the HF re-orientation process in heterogeneous rocks are studied independently. The results show that the HF re-orientation process depends on the combined effect of these factors. The HF re-orientation distance increases significantly, the final HF re-orientation trajectory becomes more complex and the guiding effect of perforation on the HF propagation path is more evident with the increase of fluid rate, fluid viscosity, and perforation angle if the hydraulic fracturing is performed in relatively heterogeneous rocks, while the differential stress is the main influencing factor and is more likely to dictate the HF propagation path if the rocks become relatively homogeneous. However, increasing the fluid viscosity and fluid rate can attenuate the impact of differential stress and can promote HF propagation along the perforation direction. Besides, NFs are also the important factor affecting HF re-orientation and induce secondary HF re-orientation in some cases in heterogeneous rocks.

収録刊行物

  • machines

    machines 10 (2), 152-, 2022-02-18

    Multidisciplinary Digital Publishing Institute : MDPI

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詳細情報 詳細情報について

  • CRID
    1050298532703736448
  • DOI
    10.3390/machines10020152
  • ISSN
    20751702
  • HANDLE
    2324/4798520
  • 本文言語コード
    en
  • 資料種別
    journal article
  • データソース種別
    • IRDB
    • OpenAIRE

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