Abstract
One kind of 3D coupled thermo-hydro-mechanical-migratory model for saturated-unsaturated dual-porosity medium was established, in which the stress field and the temperature field are single, but the seepage field and the concentration field are double, and the influences of sets, spaces, angles, continuity ratios, stiffness of fractures on the constitutive relationship of the medium can be considered. The relative three-dimensional program of finite element method was also developed. By comparing with the existing computation example, reliability of the model and the program were verified. Taking a hypothetical nuclear waste repository as a calculation example, the radioactive nuclide leak was simulated numerically with both the rock mass and the buffer being unsaturated media, and the temperatures, negative pore pressures, flow velocities, nuclide concentrations and normal stresses in the rock mass were investigated. The results showed that the temperatures, negative pore pressures and nuclide concentrations in the buffer all present nonlinear changes and distributions that even though the saturation degree in porosity is only about 1/9 of that in fracture, the flow velocity of underground water in fracture is about 6 times of that in porosity because the permeability coefficient of fracture is almost four orders higher than that of porosity, and that the regions of stress concentration occur at the vicinity of two sides of the boundary between buffer and disposal pit wall.
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References
Wang J, Zheng H L, Xu G Q, et al. Geological Disposal of High Level Radioactive Waste in China: Progress in Last Decade (1991–2000) (in Chinese). Beijing: Atomic Energy Press, 2004. 1–12
TRW Environmental Safety Systems Inc. Drift scale test progress report No.1. Las Vegas: TRW Environmental Safety Systems Inc., 1998
Zhao Y L, Cao P, Zhao Y S, et al. Dual media model for thermohydro-mechanical coupling and 3D numerical simulation (in Chinese). Chin J Rock Mech Eng, 2007, 26: 4024–4031
Liu Y R, Yang Q, Huang Y S, et al. Parallel numerical analysis of coupled fluid flow and stress based on dual porosity media model (in Chinese). Chin J Rock Mech Eng, 2007, 26: 705–711
Olivella S, Gens A. Double structure THM analyses of a heating test in a fractured tuff incorporating intrinsic permeability variations. Int J Rock Mech Min Sci, 2005, 42: 667–679
Rutqvist J, Tsang C F. Analysis of thermal-hydrologic-mechanical behavior near an emplacement drift at Yucca mountain. J Contam Hydrol, 2003, 62–63: 637–652
Zhang Y J. Coupled thermo-hydro-mechanical model and finite element analyses of dual-porosity fractured medium for ubiquitous-joint rock mass (in Chinese). Chin J Rock Mech Eng, 2009, 28: 947–955
Liang B, Liu L, Xue Q, et al. Study on numerical simulation of nuclides leakage for groundwater pollution (in Chinese). J Syst Simul, 2007, 19: 261–311
Sonnenthal E, Ito A, Spycher N, et al. Approaches to modeling coupled thermal, hydrological, and chemical processes in the drift scale heater test at Yucca Mountain. Int J Rock Mech Min Sci, 2005, 42: 698–719
Wu W H, Li X K. Coupled thermo-hydro-mechanical model including mass transfer and numerical simulation for engineering clay barrier (in Chinese). Chin J Geotech Eng, 2003, 25: 188–192
Liu Z J, Li X K, Wu W H. A constitutive model and numerical simulation for coupled chemo-thermo-hydro-mechanical process in porous media (in Chinese). Chin J Geotech Eng, 2004, 26: 797–803
Zhang Y J. Model and numerical simulation for coupled thermohydro-mechanical-migratory processes considering influence of solute concentration (in Chinese). Rock Soil Mech, 2008, 29: 212–218
Leiws R W, Schrefler B A. The Finite Element Method in the Static and Dynamic Deformation and Consolidation of Porous media. Chichester, West Sussex: Wiley, 1998
Chijimatsu M, Kurikami H, Ito A, et al. Implication of THM coupling on the near-field of a nuclear waste repository in a homogeneous rock mass. DECOVALES III-Task3-Bench Mark Test 1(BMT1)-Subtask BMT1-B, 2002. 1–43
Nishigaki M. Density dependent transport analysis saturated-unsaturated porous media-3 dimensional eulerian lagrangian method. Okayama University, 2001
Elsworth D, Mao B. Flow-deformation response of dual-porosity media. J Geotech Eng, 1992, 118: 107–124
Rutqvist J, Barr D, Datta R, et al. Coupled thermal-hydrologicalmechanical analyses of the Yucca Mountain Drift Scale Test-Comparison of field measurements to predictions of four different numerical models. Int J Rock Mech Min Sci, 2005, 42: 680–69
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Zhang, Y., Zhang, W. 3D thermo-hydro-mechanical-migratory coupling model and FEM analyses for dual-porosity medium. Sci. China Technol. Sci. 53, 2172–2182 (2010). https://doi.org/10.1007/s11431-010-4031-3
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DOI: https://doi.org/10.1007/s11431-010-4031-3