
doi: 10.2172/6601631
Lawrence Berkeley Laboratory (LBL) is contracted by the US Department of Energy to provide an auxiliary modeling effort for the Stripa Project. Within this effort, we are making calculations of inflow to the Simulated Drift Experiment (SDE), i.e. inflow to six parallel, closely spaced D-holes, using a preliminary set of data collected in five other holes, the N- and W-holes during Stages 1 and 2 of the Site Characterization and Validation (SCV) project. Our approach has been to focus on the fracture zones rather than the general set of ubiquitous fractures. Approximately 90% of all the water flowing in the rock is flowing in fracture zones which are neither uniformly conductive nor are they infinitely extensive. Our approach has been to adopt the fracture zone locations as they have been identified with geophysics. We use geologic sense and the original geophysical data to add one zone where significant water inflow has been observed that can not be explained with the other geophysical zones. This report covers LBL's preliminary prediction of flow into the D-holes. Care should be taken in interpreting the results given in this report. As explained below, the approach that LBL has designed for developing a fracture hydrologymore » model requires cross-hole hydrologic data. Cross-hole tests are planned for Stage 3 but were unavailable in Stage 1. As such, we have inferred from available data what a cross-hole test might show and used this synthetic data to make a preliminary calculation of the inflow into the D-holes. Then using all the Stage 3 data we will calculate flow into the Validation Drift itself. The report mainly demonstrates the use of our methodology and the simulated results should be considered preliminary.« less
58 Geosciences, Geologic Fractures, 540310 -- Environment, Storage, Surveys, Annealing, Western Europe 580000* -- Geosciences, Radioactive Materials, Geophysical Surveys, Mine Shafts, Ground Water, Radioactive Wastes, Wastes, 54 Environmental Sciences, Mass Transfer, Materials, Fluid Flow, Hydrogen Compounds, Environmental Transport, Calculation Methods, Sweden, Boreholes, Mathematical Models, Underground Storage, Water, Heat Treatments, Geologic Structures, Cavities, Site Characterization, Europe, Geophysics, Aquatic-- Basic Studies-- (1990-), Flow Models, Shaft Excavations, Scandinavia, Hydrology, Oxygen Compounds, Simulation
58 Geosciences, Geologic Fractures, 540310 -- Environment, Storage, Surveys, Annealing, Western Europe 580000* -- Geosciences, Radioactive Materials, Geophysical Surveys, Mine Shafts, Ground Water, Radioactive Wastes, Wastes, 54 Environmental Sciences, Mass Transfer, Materials, Fluid Flow, Hydrogen Compounds, Environmental Transport, Calculation Methods, Sweden, Boreholes, Mathematical Models, Underground Storage, Water, Heat Treatments, Geologic Structures, Cavities, Site Characterization, Europe, Geophysics, Aquatic-- Basic Studies-- (1990-), Flow Models, Shaft Excavations, Scandinavia, Hydrology, Oxygen Compounds, Simulation
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