The numerical simulation of thermal recovery considering rock deformation in shale gas reservoir

•Development of a new coupled fluid flow and geomechanics permeability model.•Use discrete fracture model to describe natural fractures and hydraulic fractures.•The flow mechanisms such as stress sensitivity, Knudsen diffusion are considered.•The study conducted a sensitivity analysis of the paramet...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2019-08, Vol.138, p.719-728
Main Authors: Yuan, Jianwei, Jiang, Ruizhong, Cui, Yongzheng, Xu, Jianchun, Wang, Qiong, Zhang, Wei
Format: Article
Language:English
Subjects:
Adsorption
Computational fluid dynamics
Computer simulation
Deformation effects
Desorption
Discrete fracture
Fluid flow
Gas recovery
Geomechanics
Heating
Horizontal wells
Hydraulic fracturing
Hydraulics
Mathematical models
Numerical simulation
Oil recovery
Permeability
Resource recovery
Rock deformation
Sensitivity
Shale gas
Stimulation
Thermal conductivity
Thermal expansion
Thermal simulation
Thermal stimulation
Well drilling
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Summary:•Development of a new coupled fluid flow and geomechanics permeability model.•Use discrete fracture model to describe natural fractures and hydraulic fractures.•The flow mechanisms such as stress sensitivity, Knudsen diffusion are considered.•The study conducted a sensitivity analysis of the parameters in the thermal recovery. Recently, shale gas is a hot spot of research as an unconventional resource. Advances in horizontal well drilling technology and fracturing technology have contributed to increased shale gas recovery. Different from conventional gas reservoirs, the adsorption gas content is as high as 85%, so the amount of adsorbed gas liberated from the matrix surface is very helpful for ultimately improving the recovery of shale gas. Recently, some progress has been made in the process of hydraulic fracture heating technology. The event that temperature variation promotes the release of adsorbed gas and thus enhances oil recovery has not been fully studied. In addition, during shale gas production, stress sensitivity, adsorption desorption and temperature will all have a significant effect on rock deformation, which will change the permeability of the matrix and fractures. To study the effect of thermal recovery based on coupled geomechanical effects and fluid flow. A numerical model of shale gas thermal recovery considering Knudsen diffusion, adsorption desorption and stress sensitivity was established to reflect the production process of shale gas. Moreover, discrete fracture is employed to describe hydraulic fractures and natural fractures. The influence of thermal expansion on rock deformation is considered in the geomechanical effect, and the permeability formula suitable for shale gas thermal recovery is developed. Finally, the effects of different parameters on thermal recovery were studied separately. It is obvious that heating hydraulic fractures improves the recovery of shale gas by promoting the liberate of adsorbed gas. A large amount of adsorbed gas is produced as the stimulation temperature increases. Considering the stress-sensitive permeability can more accurately reflect the change of permeability in the shale gas thermal recovery process, so as to more accurately predict the production of shale gas. The increase in recovery rate of shale gas thermal recovery depends on the stimulation temperature, bottom hole pressure, matrix heat capacity, thermal conductivity, Langmuir volume and matrix permeability. The larger the Langmuir volu
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2019.04.098