2019-Sustainable Industrial Processing Summit
SIPS2019 Volume 7: Schrefler Intl. Symp. / Geomechanics and Applications for Sustainable Development

Editors:F. Kongoli, E. Aifantis, A. Chan, D. Gawin, N. Khalil, L. Laloui, M. Pastor, F. Pesavento, L. Sanavia
Publisher:Flogen Star OUTREACH
Publication Year:2019
Pages:190 pages
ISBN:978-1-989820-06-3
ISSN:2291-1227 (Metals and Materials Processing in a Clean Environment Series)
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    Robust Simulation of Dynamic Hydraulic Fracturing in Naturally Fractured Formations

    Mohammad Vahab1; Mohammadreza Hirmand2; Katerina D. Papoulia3; Nasser Khalili1;
    1UNSW, Sydney, Australia; 2UNIVERSITY OF WATERLOO, Waterloo, Canada; 3APPLIED MATHEMATICS, UNIVERSITY OF WATERLOO, Waterloo, Canada;
    Type of Paper: Keynote
    Id Paper: 7
    Topic: 51

    Abstract:

    In this study, an energy based hydro-mechanical model and computational algorithm for the problem of hydraulically driven fracture networks developing in naturally fractured impermeable media is developed. The model is based on non-differentiable energy minimization for the dynamic deformation and fracture of the body coupled with mass balance of fluid flow within the hydro-fractures. Time-discontinuity induces spurious crack-opening velocity fields which lead to nonphysical solutions for the coupled fluid pressure field defined locally along the crack faces. The use of a time-continuous fracture model, such as the present non-differentiable energy minimization approach, is crucial for the numerical soundness and stability of the hydraulic fracture propagation algorithm. A discontinuous Galerkin finite element formulation is implemented, in which every element edge in the mesh is a potential site of hydro-fracture initiation and propagation. The presence of pre-existing natural fractures, as a common challenge in nearly all geological formations, are modelled with desirable edibility by simply assigning different fracture properties to the element edges defining the natural fractures. Using the graph theory principals, a search algorithm is proposed to identify, among all, the sub-set of cracked interfaces that form the interconnected hydraulically loaded fracture network. Robustness of the proposed computational algorithm and its versatility in the study of hydraulic fracturing is shown through several numerical simulations.

    Keywords:

    Applications; Geomechanics;

    References:

    [1] M.R. Hirmand, K. D. Papoulia, Int. J. Numer. Meth. Eng. 115 (2018) 627-650.
    [2] M. Vahab, N. Khalili, Rock. Mech. Rock. Eng. 51(2018) 3219-3239
    [3] A.R. Khoei, M. Vahab, E. Haghighat, S. Moallemi, Int. J. Fract. 188 (2014) 79-108.

    Cite this article as:

    Vahab M, Hirmand M, Papoulia K, Khalili N. (2019). Robust Simulation of Dynamic Hydraulic Fracturing in Naturally Fractured Formations. In F. Kongoli, E. Aifantis, A. Chan, D. Gawin, N. Khalil, L. Laloui, M. Pastor, F. Pesavento, L. Sanavia (Eds.), Sustainable Industrial Processing Summit SIPS2019 Volume 7: Schrefler Intl. Symp. / Geomechanics and Applications for Sustainable Development (pp. 93-98). Montreal, Canada: FLOGEN Star Outreach