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One dimensional models of hydraulic fracture

One dimensional models of hydraulic fracture. Anthony Peirce (UBC) Collaborators: Jose` Adachi (SLB) Shira Daltrop (UBC) Emmanuel Detournay (UMN). WITS University 1 April 2009. Outline. The HF problem and 2D models Slender geometries -> the possibilities for 1D models

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One dimensional models of hydraulic fracture

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  1. One dimensional models of hydraulic fracture Anthony Peirce (UBC) Collaborators: Jose` Adachi (SLB) Shira Daltrop (UBC) Emmanuel Detournay (UMN) WITS University 1 April 2009

  2. Outline • The HF problem and 2D models • Slender geometries -> the possibilities for 1D models • The classic PKN model – porous medium eq – limitations • Extension of PKN to include toughness - 1D integro-PDE • P3D model – PKN methodology ->pseudo 3D • Conclusions

  3. HF Examples - block caving

  4. HF Example – caving (Jeffrey, CSIRO)

  5. Oil well stimulation

  6. Lab test with stress contrast (Bunger)

  7. 2-3D HF Equations • Elasticity • Lubrication • Boundary conditions at moving front (non-locality) (non-linearity) (free boundary)

  8. The PKN Model

  9. Assumptions behind the PKN Model • Pressure independent of : • Vertical sections approximately in a state of plane strain: • PKN model: • Local elasticity equation Can’t model pressure singularities for example when

  10. PKN – Averaging the Lubrication Eq

  11. Scaled lubrication & similarity solution

  12. Numerical soln of a finger-like frac

  13. Width and scaled pressures

  14. Asymptotics of numerical soln

  15. Extended PKN:2D integral eq 1D integral eq • Integral eq for a pressurized rectangular crack • Re-scale variables:

  16. Asymptotic behaviour of the kernel ~ Hilbert Transform PKN

  17. Assumed behaviour of • Power law in the tip regions: • Analytic away from the tips:

  18. Outer expansion Hilbert Transform Region PKN Region PKN

  19. Outer expansion Test function:

  20. Inner expansion: Hilbert Transform Region PKN Region

  21. Inner Expansion

  22. Discretizing the Elasticity Equation

  23. Discretizing the Fluid Flow Equation

  24. EPKN Tip solutions – viscosity Close to the tip

  25. Locating the tip position Viscosity Dominated: Toughness Dominated:

  26. Numerical Results K=0

  27. Numerical Results K=1

  28. Numerical Results K=5

  29. P3D models

  30. Scaled elasticity equations

  31. Averaged equations

  32. Scaled lubrication equation

  33. Collocation scheme to solve ODE

  34. Numerical Results

  35. Footprint comparison with 3D solution

  36. Width comparison with 3D solution

  37. Concluding remarks • The HF problem and 2D models • Slender geometries -> the possibilities for 1D models • The classic PKN model – porous medium eq - limitations • Extension of PKN to include toughness - 1D integro-PDE • Reduction of the 2D integral to a 1D nonlocal equation in the small aspect ratio limit • Asymptotics of the 1D kernel • Asymptotic analysis to determine the action of the integral operator in different regions of the domain: • Outer region: 1D integral equation - local PDE • Inner tip region: 1D integral equation - Hilbert Transform • Tip asymptotics and numerical solution • P3D model – PKN methodology ->pseudo 3D • Plane strain width solution and averaging • Averaging and scaling the lubrication • Reduction to a convection diffusion equation • Numerical solution via collocation • Results and comparison with 3D solution

  38. PKN Traveling Wave solution

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