Research of fracture initiation and propagation in HDR fracturing under thermal stress from meso-damage perspective

By HDR (hot dry rock) fracturing the deep buried geothermal energy can be efficiently extracted from the established EGS (enhanced geothermal system). While the fracture initiation and propagation is subjected to the interaction of cryogenic induced thermal stress and liquid pressure. Based on the m...

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Bibliographic Details
Published in:Energy (Oxford) 2019-07, Vol.178, p.508-521
Main Authors: Zhang, Wei, Guo, Tian-kui, Qu, Zhan-qing, Wang, Zhiyuan
Format: Article
Language:English
Subjects:
Crack initiation
Crack propagation
Damage
Enhanced geothermal system
Enhanced geothermal systems
Fracture mechanics
Geothermal energy
HDR fracturing
Heat transfer
Heat transfer coefficients
High temperature
High-temperature fracturing test
Hydraulic fracturing
Mathematical models
Mathematical morphology
Mechanical properties
Modulus of elasticity
Pressure
Process parameters
Propagation
Rocks
Seepage
Stress propagation
Temperature
Temperature effects
Thermal stress
THM-Damage model
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Summary:By HDR (hot dry rock) fracturing the deep buried geothermal energy can be efficiently extracted from the established EGS (enhanced geothermal system). While the fracture initiation and propagation is subjected to the interaction of cryogenic induced thermal stress and liquid pressure. Based on the meso-damage mechanics, elastic thermodynamics and Biot seepage mechanics, a mesoscopic thermo-hydro-mechanical-damage coupling model (THM-damage) is proposed to analyze the fracturing stimulation in HDR. Firstly, the mathematical model and numerical implementation method is validated by high-temperature granite fracturing experiments. Secondly, the action mechanism of thermal stress in hydraulic fracturing of HDR is discussed. Thirdly, the evolution of multiple physical fields during the initiation and propagation of HDR fracturing is researched. Finally, the effects of various parameters on HDR fracturing process are also studied. The results indicate that when the rock temperature exceeds 200 °C the fracture network can be formed by hydraulic fracturing, which extends along the direction perpendicular to the minimum in-situ stress. Increasing rock temperature can reduce fracture initiation pressure and rock failure pressure. The heat transfer coefficient between fracturing fluid and rock and the rock Young’s modulus have influence on the fracture morphology during HDR fracturing under thermal stress. •High-temperature granite fracturing experiments under triaxial stress are conducted to validate the THM-damage model.•Action mechanism of thermal stress in HDR fracturing is discussed.•Evolution of temperature, seepage, stress and damage field during HDR fracturing are researched.•Effects of various parameters on fracture morphology of HDR fracturing are studied.
ISSN:0360-5442
1873-6785
DOI:10.1016/j.energy.2019.04.131