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Convective Thermo-Poroelasticity in Non-Boiling Geothermal Reservoirs

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Presentation on theme: "Convective Thermo-Poroelasticity in Non-Boiling Geothermal Reservoirs"— Presentation transcript:

1 Convective Thermo-Poroelasticity in Non-Boiling Geothermal Reservoirs
EGEE 520 Kate (Kritika Trakoolngam)

2 Geothermal Energy Alternative energy Geothermal reservoir
Dual porosity medium

3 Governing Equations - I
Mechanical Behavior Hooke’s Law Thermal Mechanical Hydraulic (Effective stress)

4 Governing Equations - II
Compliance Matrix for discontinuous rock mass (Amadei & Goodman 1981) Normal stiffness of rock mass Shear stiffness of rock mass Fracture spacing

5 Governing Equations - III
Hydraulic Behavior Darcy’s Law (Advective flow) Fluid mass transfer between matrix and fracture (Warren & Root 1963) Matrix Mechanical (Consolidation) Thermal (Volumetric strain) Fracture

6 Governing Equations - III
Thermal Behavior Fick’s Law (Conduction) Mechanical (Volumetric strain) Convection Hydraulic Storage

7 FEM Formulation

8 FEMLAB Solution Models Materials Equation system Mechanical
Mechanical Stress-strain  u, v, w Darcy’s Flow (matrix)  p1 Darcy’s Flow (fracture)  p2 Thermal conduction + convection (matrix)  cc1 Thermal conduction + convection (fracture)  cc2 Materials Equation system Mechanical Water Quartz Fracture Matrix Rock mass (mat3_sE_1_1_*px+mat3_sE_1_2_*px+ mat3_sE_1_3_*px+ mat3_sE_1_4_*px+ mat3_sE_1_5_*px+ mat3_sE_1_6_*px)

9 Validation Displacements Flow velocity Heat flux Fracture Matrix

10 Parametric Results Heat Flux Thermal expansion Temp ~ 150 c
Heat flux 1000 MW/m2 Cold water

11 Conclusions FEMLAB Flexibility Functionality

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