Finite Difference Simulation of Geologically Complex Reservoirs With Tensor Permeabilities

Lee, S.H.; Durlofsky, Louis J.; Lough, M.F.; Chen, W.H.

doi:10.2118/52637-pa

Cited by 54 publications

(15 citation statements)

References 15 publications

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S ummaryThe derivation of algebraic flux continuity conditions for full tensor discretization operators has lead to efficient and robust locally conservative flux continuous finite volume methods for determining the discrete velocity field in subsurface reservoirs e .g [1][2][3][4][5][6][7][8] .

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mentioning

confidence: 99%

Symmetric Positive Definite General Tensor Discretization Operators on Unstructured and Flow Based Grids

Edwards¹

2002

ECMOR VIII - 8th European Conference on the Mathematics of Oil Recovery

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confidence: 99%

Symmetric Positive Definite General Tensor Discretization Operators on Unstructured and Flow Based Grids

Edwards¹

2002

ECMOR VIII - 8th European Conference on the Mathematics of Oil Recovery

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“…An important aspect of coarsening is that K c becomes often anisotropic, even if the original hydraulic permeability K is isotropic. Recently, methods became available that cope with the off-diagonal components in a tensor [Aavatsmark et al, 1996;Lee et al, 1998;Anderman et al, 2002].…”

Section: Coarse-scale Equationsmentioning

confidence: 99%

Limitations to upscaling of groundwater flow models dominated by surface water interaction

Vermeulen

Stroet

Heemink

2006

Water Resources Research

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[1] Different upscaling methods for groundwater flow models are investigated. A suite of different upscaling methods is applied to several synthetic cases with structured and unstructured porous media. Although each of the methods applies best to one of the synthetic cases, no performance differences are formed if the methods were applied to a real three-dimensional case. Furthermore, we focus on boundary conditions, such as Dirichlet, Neumann, and Cauchy conditions, that characterize the interaction of groundwater with, for example, surface water and recharge. It follows that the inaccuracy of the flux exchange between boundary conditions on a fine scale and the hydraulic head on a coarse scale causes additional errors that are far more significant than the errors due to an incorrect upscaling of the heterogeneity itself. Whenever those errors were reduced, the upscaled model was improved by 70%. It thus follows that in practice, whenever we focus on predicting groundwater heads, it is more important to correctly upscale the boundary conditions than hydraulic transmissivity.

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“…Flux-continuons methods, designed to handle full tensor permeability and/or non-orthogonal grids, have been presented previously for two dimensional [8,10] and three dimensional systems [1,111 . Though there are differences between these various scheures, they all provide continuity of flux across cell boundaries and reduce to the usual weighted harmonic mean transmissibilities in the appropriate limit (orthogonal grid, diagonal permeability tensors) .…”

Section: Multi -Point Flux Continuous Finite-difference Schem Ementioning

confidence: 99%

“…Multi-point discretization scheme is used for the flux formulation in order to treat grid non-orthogonalities and anisotropic permeability fields correctly . A general finite-volume discretization scheme for nonorthogonal hexahedron grids with tensor permeability leads to wide stencils (9-pt in 2D [8,10] and 27-pt in 3D [1,11]) . We employ the wide stencil derived by the finite-volume method of Lee et al .…”

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confidence: 99%

A Black-Oil Reservoir Simulator for Hexahedral Multiblock Grids

Lee¹,

Jenny²,

Wolfsteiner³

2002

ECMOR VIII - 8th European Conference on the Mathematics of Oil Recovery

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A black oil reservoir simulator was developed for hexahedral minti-block grids . An objectoriented approach for the design and implementation of the simulator was adopted . We discuss the general features and object-oriented (0/0) design of the simulator.Complexity in geological or well features in a reservoir model (e .g., faults, inclined and multi-lateral wens) entails non-orthogonal and/or unstructured grids in place of conventional Cartesian grids . To obtain flexibility in gridding as well as numerical efficiency, hexahedral minti-block grids are employed . These multiblock are locally structured and globall y unstructured.In general, one can always generate multiblock grids with matched grids at block boundaries, and that leads to simple data structuren and communication patterns between blocks . Nevertheless, when geometrical boundaries (e .g. fault surfaces) become complex, multiblock grid with matched grids tends to create many blocks with small cells . We generalize the multiblock grid to the case where the gridlines do not match at block boundaries . The general quality and characteristics of multiblock grids, with matched or unmatched grids at the block boundaries, are discussed .Minti-point discretization scheures are necessary to accommodate non-orthogonal grid and tensor permeability . A flux-continuous finite difference scheme, which was previously developed for hexahedral grids with tensor permeability, is extended to multiblock systems with unmatched grids . We also present efficient iterative solution scheures that take advantage of the locally structured character of the computational grid .We demonstrate the capabilities of this generalized multiblock approach using examples of practical interest : (1) An SPE comparative study and (2) a real reservoir model with multiple complex faults and internal surfaces .

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Finite Difference Simulation of Geologically Complex Reservoirs With Tensor Permeabilities

Cited by 54 publications

References 15 publications

Symmetric Positive Definite General Tensor Discretization Operators on Unstructured and Flow Based Grids

Symmetric Positive Definite General Tensor Discretization Operators on Unstructured and Flow Based Grids

Limitations to upscaling of groundwater flow models dominated by surface water interaction

A Black-Oil Reservoir Simulator for Hexahedral Multiblock Grids

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