DarcyTools: A Computer Code for  Hydrogeological Analysis of Nuclear Waste Repositories in Fractured Rock

Urban Svensson; Michel Ferry

doi:10.4236/jamp.2014.26044

Journal of Applied Mathematics and Physics > Vol.2 No.6, May 2014

DarcyTools: A Computer Code for Hydrogeological Analysis of Nuclear Waste Repositories in Fractured Rock

Urban Svensson, Michel Ferry
Computer-aided Fluid Engineering AB, Frankes v?g 3, 371 65 Lyckeby, Sweden.
MFRDC, 6 rue de la Perche, 44700 Orvault, France.
DOI: 10.4236/jamp.2014.26044 PDF HTML 5,211 Downloads 6,925 Views Citations

Abstract

A computer code for simulation of groundwater flow and transport is described. Both porous and fractured media are handled by the code. The main intended application is the analysis of a deep repository for nuclear waste and for this reason flow and transport in a sparsely fractured rock is in focus. The mathematical and numerical models are described in some detail. In short, one may say that the code is based on the traditional conservation and state laws, but also embodies a number of submodels (subgrid processes, permafrost, etc). An unstructured Cartesian grid and a finite volume approach are the key elements in the discretization of the basic equations. A multigrid solver is part of the code as well as a parallelization option based on the SPMD (Single-Program Multiple-Data) method. The main application areas are summarized and an application to a deep repository is discussed in some more detail.

Keywords

Fractured Rock, Inflow Prediction, Deep Repository

Share and Cite:

Svensson, U. and Ferry, M. (2014) DarcyTools: A Computer Code for Hydrogeological Analysis of Nuclear Waste Repositories in Fractured Rock. Journal of Applied Mathematics and Physics, 2, 365-383. doi: 10.4236/jamp.2014.26044.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	Jackson, C.P., Andrew, R.H. and Todman, S. (2000) Self-Consistency of Heterogeneous Continuum Porous Medium Representation of a Fractured Medium. Water Resources Research, 36, 189-202. http://dx.doi.org/10.1029/1999WR900249
[2]	Sahimi, M. (1995) Flow and Transport in Porous Media and Fractured Rock: From Classical Methods to Modern Approaches. VCH., Weinheim, 482pp.
[3]	Hartley, L. and Joyce, S. (2013) Approaches and Algorithms for Groundwater Flow Modeling in Support of Site Investigations and Safety Assessment of the Forsmark Site, Sweden. Journal of Hydrology.
[4]	Svensson, U., Ferry, M. and Kuylenstierna, H.-O. (2010) DarcyTools, Version 3.4. Concepts, Methods and Equations. SKB R-10-70, Svensk K?rnbr?nslehantering AB. 144pp.
[5]	Svensson, U. and Ferry, M. (2010) DarcyTools, Version 3.4. User’s Guide. SKB R-10-72, Svensk K?rn-br?nslehantering AB.
[6]	Svensson, U. (2010) DarcyTools, Version 3.4. Verification, Validation and Demonstration. 2010, SKB R-10-71, Svensk K?rnbr?nslehantering AB.
[7]	Pruess, K. (1991) TOUGH2 a General-Purpose Numerical Simulator for Multiphase Fluid and Heat Flow. Report, LBNL-29400, Lawrence Berkeley Laboratory, Berkeley, Ca.
[8]	McDonald, M.G. and Harbaugh, A.W. (1988) A Modular Three-Dimensional Finite-Difference Ground-Water Flow Model. 1988, U.S. Geol. Surv. Tech. Water Resour. Invest. Book 6, Chap. 2.
[9]	Hammond, G.E. and Lichtner, P.C. (2010) Field-Scale Model for the Natural Attenuation of Uranium at the Hanford Area Using High-Performance Computing. Water Resources Research, 46, WO9527. http://dx.doi.org/10.1029/2009WR008819
[10]	Dershowitz, W., Lee, G., Geier, J., Foxford, T. and Ahlstrom, E. (1999) FracMan Interactive Discrete Feature Data Analysis, Geometric Modeling, and Exploration Simulation. User Docu-mentation, Version 2.6, Golder Associates Inc.
[11]	Bian, H.B., Jia, Y., Amand, G., Duveau, G. and Shao, J.F. (2012) 3D Numerical Modeling Thermo-Hydromechanical Behavior of Underground Storages in Clay Rock. Tunnelling and Underground Space Technology, 30, 93-109. http://dx.doi.org/10.1016/j.tust.2012.02.011
[12]	Haggerty, R. and Gorelick, S.M. (1995) Multiple-Rate Mass Transfer for Modeling Diffusion and Surface Reaction in Media with Pore-Scale Heterogeneity. Water Resources Research, 31, 2383-2400. http://dx.doi.org/10.1029/95WR10583
[13]	Svensson, U. (2001) A Continuum Representation of Fracture Networks. Part I: Method and Basic Test Cases. Journal of Hydrology, 250, 170-186. http://dx.doi.org/10.1016/S0022-1694(01)00435-8
[14]	Svensson, U. (2001) A Continuum Representation of Fracture Networks. Part II: Application to the ?sp? Hard Rock Laboratory. Journal of Hydrology, 250, 187-205. http://dx.doi.org/10.1016/S0022-1694(01)00436-X
[15]	Diskin, B., Thomas, J.L., Nielsen, E.J., Nishikawa, H. and White, J.A. (2010) Comparison of Node-Centered and Cell- Centered Unstructured Finite-Volume Discretizations: Viscous Fluxes. American Institute of Aeronautics and Astronautics, 48.
[16]	Spalding, D.B. (1972) A Novel Finite Difference Formulation for Differential Expressions Involving Both First and Second Derivatives. International Journal for Numerical Methods in Engineering, 4, 551-559. http://dx.doi.org/10.1002/nme.1620040409
[17]	Roache, P.J. (1976) Computational Fluid Dynamics. Hermosa Publs., Albuquerque, 446pp.
[18]	Aftosmis, M.J., Berger, M.J. and Melton, J.E. (1999) Adaptive Cartesian Mesh Generation. In: Thompson, J.F., Soni, B.K. and Weatherill, N.P., Eds., Handbook of Grid Generation, CRC Press, Boca Raton, 1136pp.
[19]	Saad, Y. and Schultz, M.H. (1996) GMRES: A Generalized Minimal Residual Algorithm for Solving Nonsymmetric Linear Systems. SIAM Journal of Scientific and Statistical Computing, 7, 856-869.
[20]	Stüben, K. and Trottenberg, U. (1982) Multigrid Methods: Fundamental Algorithms, Model Problem Analysis and Applications. Mul-tigrid Methods, Lecture Notes in Mathematics, 960, 176.
[21]	Stüben, K. (2001) Algebraic Multigrid (AMG): An In-troduction with Applications. In: Trottenberg, U., Oosterlee, C. and Schüller, A., Eds., Multigrid, Academic Press, London,
[22]	Ferry, M. (2002) New Features of MIGAL Solver. 9th International PHOENICS Users Conference, Moscow.
[23]	Aftosmis, M.J., Berger, M.J. and Murman, S.M. (2004) Applications of Space-Filling Curves to Carte-sian Methods for CFD. 42nd AIAA, Aerospace Sciences Meeting and Exhibition, Chapter.
[24]	Sagan, H. (1994) Space Filling Curves. Springer-Verlag, 193pp. http://dx.doi.org/10.1007/978-1-4612-0871-6
[25]	Selroos, J-O. and Follin, S. (2010) SR-Site Groundwater Flow Modeling Methodology, Setup and Results. SKB R-09-22, Svensk K?rn-br?nslehantering AB. 125pp.
[26]	Vidstrand, P., Follin, S. and Zugec, N. (2010) Groundwater Flow Modeling of Pe-riods with Periglacial and Glacial Climate Conditions—Forsmark. SKB R-09-21, 190pp, Svensk K?rnbr?nslehantering AB.
[27]	Svensson, U. and Follin, S. (2010) Groundwater Flow Modelling of the Excavation and Operational Phases—Forsmark. SKB R-09-19, Svensk K?rnbr?nslehantering AB.
[28]	Joyce, S., Applegate, D., Hartley, L., Hoek, J., Simpson, T., Swan, D. and Marsic, N, (2010) Groundwater Flow Modelling of Periods with Temperate Climate Conditions—SR-Site Forsmark. SKB R-09-20, 2010, Svensk K?rnbr?nslehantering AB.

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