Phase-field cohesive zone modeling of hydro-thermally induced fracture in hot dry rock during liquid nitrogen fracturing

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autorschaft

  • Ruiyue Yang
  • Chunyang Hong
  • Yanjin Gong
  • Zhongwei Huang
  • Navid Valizadeh
  • Shuwei Zhou
  • Gensheng Li
  • Xiaoying Zhuang

Organisationseinheiten

Externe Organisationen

  • China Univeristy of Petroleum - Beijing
  • Tongji University
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Details

OriginalspracheEnglisch
Aufsatznummer120070
Seitenumfang18
FachzeitschriftRenewable energy
Jahrgang223
Frühes Online-Datum29 Jan. 2024
PublikationsstatusVeröffentlicht - März 2024

Abstract

Liquid nitrogen (LN2) fracturing is regarded as a viable alternative for the efficient development of hot dry rock (HDR) resources due to its main advantage in producing complex fracture networks and lowering breakdown pressure. However, the fracturing mechanisms and major factors controlling the LN2 fracturing efficiency are still poorly understood. A thermo-hydro-mechanical-damage (THMD) coupling model is proposed to study the fracture initiation/propagation behavior of LN2 fracturing under various fracturing parameters and reservoir conditions based on a phase-field cohesive zone method (PF-CZM). The characteristic differences between LN2 and water fracturing are compared. Results indicate that the tensile stress of LN2 fracturing is concentrated at the tip of fractures. When the HDR reservoirs are undertaken lower stress level with higher initial rock temperature, the damage ratio can be enhanced. Young's modulus and thermal expansion coefficient are the key petrophysical and mechanical properties affecting the LN2 fracturing performance. The optimal pressurization rate is 0.2 MPa/s. It indicated that a balanced contribution of thermal stress and fluid pressure is crucial to the bifurcation of major fracture and forming complex fracture networks. The major findings of the study are expected to provide theoretical guidance and computational simulation basis for the LN2 fracturing on HDR reservoirs.

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Phase-field cohesive zone modeling of hydro-thermally induced fracture in hot dry rock during liquid nitrogen fracturing. / Yang, Ruiyue; Hong, Chunyang; Gong, Yanjin et al.
in: Renewable energy, Jahrgang 223, 120070, 03.2024.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Yang, R., Hong, C., Gong, Y., Huang, Z., Valizadeh, N., Zhou, S., Li, G., & Zhuang, X. (2024). Phase-field cohesive zone modeling of hydro-thermally induced fracture in hot dry rock during liquid nitrogen fracturing. Renewable energy, 223, Artikel 120070. https://doi.org/10.1016/j.renene.2024.120070
Yang R, Hong C, Gong Y, Huang Z, Valizadeh N, Zhou S et al. Phase-field cohesive zone modeling of hydro-thermally induced fracture in hot dry rock during liquid nitrogen fracturing. Renewable energy. 2024 Mär;223:120070. Epub 2024 Jan 29. doi: 10.1016/j.renene.2024.120070
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title = "Phase-field cohesive zone modeling of hydro-thermally induced fracture in hot dry rock during liquid nitrogen fracturing",
abstract = "Liquid nitrogen (LN2) fracturing is regarded as a viable alternative for the efficient development of hot dry rock (HDR) resources due to its main advantage in producing complex fracture networks and lowering breakdown pressure. However, the fracturing mechanisms and major factors controlling the LN2 fracturing efficiency are still poorly understood. A thermo-hydro-mechanical-damage (THMD) coupling model is proposed to study the fracture initiation/propagation behavior of LN2 fracturing under various fracturing parameters and reservoir conditions based on a phase-field cohesive zone method (PF-CZM). The characteristic differences between LN2 and water fracturing are compared. Results indicate that the tensile stress of LN2 fracturing is concentrated at the tip of fractures. When the HDR reservoirs are undertaken lower stress level with higher initial rock temperature, the damage ratio can be enhanced. Young's modulus and thermal expansion coefficient are the key petrophysical and mechanical properties affecting the LN2 fracturing performance. The optimal pressurization rate is 0.2 MPa/s. It indicated that a balanced contribution of thermal stress and fluid pressure is crucial to the bifurcation of major fracture and forming complex fracture networks. The major findings of the study are expected to provide theoretical guidance and computational simulation basis for the LN2 fracturing on HDR reservoirs.",
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author = "Ruiyue Yang and Chunyang Hong and Yanjin Gong and Zhongwei Huang and Navid Valizadeh and Shuwei Zhou and Gensheng Li and Xiaoying Zhuang",
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T1 - Phase-field cohesive zone modeling of hydro-thermally induced fracture in hot dry rock during liquid nitrogen fracturing

AU - Yang, Ruiyue

AU - Hong, Chunyang

AU - Gong, Yanjin

AU - Huang, Zhongwei

AU - Valizadeh, Navid

AU - Zhou, Shuwei

AU - Li, Gensheng

AU - Zhuang, Xiaoying

N1 - Funding Information: This research was supported by the National Natural Science Foundation of China ( 52192621 , 52020105001 ) and China Scholarship Council ( 202106440070 ).

PY - 2024/3

Y1 - 2024/3

N2 - Liquid nitrogen (LN2) fracturing is regarded as a viable alternative for the efficient development of hot dry rock (HDR) resources due to its main advantage in producing complex fracture networks and lowering breakdown pressure. However, the fracturing mechanisms and major factors controlling the LN2 fracturing efficiency are still poorly understood. A thermo-hydro-mechanical-damage (THMD) coupling model is proposed to study the fracture initiation/propagation behavior of LN2 fracturing under various fracturing parameters and reservoir conditions based on a phase-field cohesive zone method (PF-CZM). The characteristic differences between LN2 and water fracturing are compared. Results indicate that the tensile stress of LN2 fracturing is concentrated at the tip of fractures. When the HDR reservoirs are undertaken lower stress level with higher initial rock temperature, the damage ratio can be enhanced. Young's modulus and thermal expansion coefficient are the key petrophysical and mechanical properties affecting the LN2 fracturing performance. The optimal pressurization rate is 0.2 MPa/s. It indicated that a balanced contribution of thermal stress and fluid pressure is crucial to the bifurcation of major fracture and forming complex fracture networks. The major findings of the study are expected to provide theoretical guidance and computational simulation basis for the LN2 fracturing on HDR reservoirs.

AB - Liquid nitrogen (LN2) fracturing is regarded as a viable alternative for the efficient development of hot dry rock (HDR) resources due to its main advantage in producing complex fracture networks and lowering breakdown pressure. However, the fracturing mechanisms and major factors controlling the LN2 fracturing efficiency are still poorly understood. A thermo-hydro-mechanical-damage (THMD) coupling model is proposed to study the fracture initiation/propagation behavior of LN2 fracturing under various fracturing parameters and reservoir conditions based on a phase-field cohesive zone method (PF-CZM). The characteristic differences between LN2 and water fracturing are compared. Results indicate that the tensile stress of LN2 fracturing is concentrated at the tip of fractures. When the HDR reservoirs are undertaken lower stress level with higher initial rock temperature, the damage ratio can be enhanced. Young's modulus and thermal expansion coefficient are the key petrophysical and mechanical properties affecting the LN2 fracturing performance. The optimal pressurization rate is 0.2 MPa/s. It indicated that a balanced contribution of thermal stress and fluid pressure is crucial to the bifurcation of major fracture and forming complex fracture networks. The major findings of the study are expected to provide theoretical guidance and computational simulation basis for the LN2 fracturing on HDR reservoirs.

KW - Fracture propagation

KW - Hot dry rock

KW - Hydro-thermally induced fracture

KW - Liquid nitrogen fracturing

KW - Phase-field model

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