Nodal and Mixed Finite Elements for the Numerical Homogenization of 3D Permeability |
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Authors: | Anna Trykozko Wouter Zijl Alain Bossavit |
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Affiliation: | (1) Center for Subsurface Modeling – C0200, Texas Institute for Computational and Applied Mathematics, The University of Texas at Austin, Austin, TX 78712, USA |
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Abstract: | The aim of upscaling is to determine equivalent homogeneous parameters at a coarse-scale from a spatially oscillating fine-scale parameter distribution. To be able to use a limited number of relatively large grid-blocks in numerical oil reservoir simulators or groundwater models, upscaling of the permeability is frequently applied. The spatial fine-scale permeability distribution is generally obtained from geological and geostatistical models. After upscaling, the coarse-scale permeabilities are incorporated in the relatively large grid-blocks of the numerical model. If the porous rock may be approximated as a periodic medium, upscaling can be performed by the method of homogenization. In this paper the homogenization is performed numerically, which gives rise to an approximation error. The complementarity between two different numerical methods – the conformal-nodal finite element method and the mixed-hybrid finite element method – has been used to quantify this error. These two methods yield respectively upper and lower bounds for the eigenvalues of the coarse-scale permeability tensor. Results of 3D numerical experiments are shown, both for the far field and around wells. |
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Keywords: | bilateral bounds complementarity homogenization mixed finite elements nodal finite elements |
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