OPG Meeting June 29, 2006 - PowerPoint PPT Presentation

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OPG Meeting June 29, 2006

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... continua on predicted Darcy fluxes, groundwater residence times and flow paths ... of obtaining hydraulic head and Darcy velocity distributions in the fracture and ... – PowerPoint PPT presentation

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Title: OPG Meeting June 29, 2006


1
OPG MeetingJune 29, 2006
  • Young-Jin Park, Rob McLaren and Eric Sykes
  • Department of Earth Sciences
  • Jon Sykes
  • Department of Civil Engineering

2
Agenda
  • GS16 project update
  • QA/QC work plan for UofW
  • Bruce DGR conceptual model

3
GS16 Project Update
  • Black type paragraphs from WPD
  • Blue type June 27 status of work
  • Detailed Work Description
  • The proposed work program has three elements
  • FRAC3DVS Code Improvements
  • Sub-regional Shield Flow System Case Study and
  • Visualisation Methods - Application of VRL
    Technology.
  • These work program elements are to be coordinated
    within a DGRTP Task Force on Shield Groundwater
    Flow System Characterisation and Simulation. The
    work program elements are described below

4
Code Improvements - FRAC3DVS
  • The improvements to FRAC3DVS that are to be
    included in the proposed work program include
  • inclusion and verification of temperature change
    of state in this stage of the work the impact on
    pressure of the volume change of the pore fluid
    on freezing will be neglected
  • work being completed by Stefano, will be
    documented in deliverable 13D
  • pre-processing approach for inclusion and
    improved non-orthogonal geometric realisation
    of probabilistic 3-dimensional DFN models
  • Work to be completed Rob will add necessary
    changes to NP and verify implementation in
    Frac3DVS Stefano will expand his pre-processor
    to allow for non-orthogonal fractures work to be
    reported in 13D
  • continued development/refinement of approaches to
    improve computational efficiency (ex multi-grid
    algorithms, sub-time stepping functions, domain
    decomposition strategies to take advantage of
    parallel computing infrastructure)
  • work is on-going Dua has completed multi-grid
    algorithm, mesh development algorithms to take
    advantage of multi-grids need to be developed
    Young-Jin has investigated parallelization of
    Frac3DVS Rob and Young-Jin lead the code
    improvements work results will be documented in
    13D
  • extension of time tracking strategies from
    steady-state to transient simulations
  • This work is an extension of that completed by
    Fabien Jon and Ed will undertake research on
    algorithms to expand the life expectancy
    algorithm to transient flow (possibilities
    include the adjoint method for coupled flow,
    density and transport) we will likely need an RA
    for implementation
  • development of thermo-mechanical coupling to
    address transient glacier boundary conditions
    (stress and temperature).
  • Stefano will implement the 1-D approach following
    Neuzil in his temperature algorithm Dua will be
    involved in the formulation of a more rigorous
    THM approach
  • The University of Waterloo team and HydroGeoLogic
    Limited will collaborate closely in the
    development and enhancement of FRAC3DVS. The
    QA/QC for code improvements will be the primary
    responsibility of the University of Waterloo.
    Annual summary reports (technical memorandum)
    detailing the status of improvements made to
    FRAC3DVS will be provided in 2005 and 2006.

5
Sub-regional Shield Flow System Case Study
  • This work program will be conducted as part of
    the Task Force on Shield Groundwater Flow System
    Characterisation and Simulation. As a basis for
    all simulations, the sub-regional flow domain
    described by Sykes et al. (2004) will be used.
    Specific objectives for this Case Study include
  • demonstrate influence of alternative and equally
    probably DFN models (Site 2a version) on
    estimation of flow system Darcy fluxes,
    groundwater residence times and flow paths at
    depths to 1500 m
  • work was completed by Stefano and Young-Jin
    reported at Amigo, and 2006 Geoscience workshop
  • demonstrate influence of spatially variable and
    correlated permeability fields in fracture and
    matrix continua on predicted Darcy fluxes,
    groundwater residence times and flow paths at
    depths to 1500 m
  • work was completed by Stefano and Young-Jin
    reported at Amigo, and 2006 Geoscience workshop
  • demonstrate the influence of fresh-saline-brine
    groundwater distributions on the evolution of
    groundwater with respect to TDS concentrations,
    Darcy fluxes, groundwater residence times and
    flow paths and
  • work has been initiated Stefano and Young-Jin
    have developed a work plan that will involve
    SWIFT and Frac3DVS comparisons this issue will
    be resolved and addressed in the 14D deliverable
  • demonstrate the influence of coupled
    climate/surface boundary conditions on
    groundwater flow system evolution and dynamics
    (GSM realization nn2008).
  • Stefano has completed an initial run that was
    included in our presentation at Amigo and the
    2006 Geoscience workshop the implementation of
    the thermal algorithm will be followed by
    simulations using the sub-regional domain work
    will be completed and documented in 13D or 14D
    (decision to be made)
  • demonstrate the role of dimensionality (2D vs 3D)
    on the results of simulations in the complex,
    sub-regional flow domain.
  • As of June 27, there is no lead for this task
    the analyses are very straight forward and can be
    completed by an RA supervised by Jon and Ed
    documentation will be included in 14D

6
Continued
  • As part of this work program, quarterly Task
    Force progress meetings will normally be held in
    Waterloo and/or Toronto.
  • Progress/results in the Sub-regional Shield Flow
    System Case Study will be documented in a series
    of DGRTP reports summarizing 2005 activities and
    in a final DGRTP 1200-series program report in
    2006. These reports will summarize and illustrate
    the increased level of understanding regarding
    Shield flow system characteristics and the nature
    of responses to long-term climate changes that
    contribute to demonstrating the geoscientific
    case for deep repository safety. These reports
    will also summarize the unique numerical tools
    and methodologies that have been developed to
    meet the work program objectives.
  • As a special case of the Sub-regional Flow System
    Case Study, flow modelling in support of OPGs
    participation in the international DECOVALEX
    program (GS01) will be undertaken. As part of
    GS01, the fracture zone model developed by
    Srivastava (2002) and modelled by Sykes et al.
    (2004) was systematically simplified from a 540
    fracture zone network to one consisting of 20
    fracture zones. This simplification was required
    for the purpose of undertaking coupled
    thermal-hydraulic-mechanical (THM) modelling
    using the MOTIF code. To support this
    simplification process, the reduced fracture zone
    network will be modelled in FRAC3DVS using the
    orthogonally fracture face representation,
    hydraulic conductivity assignments and boundary
    conditions as in Sykes et al. (2004) for the
    purpose of obtaining hydraulic head and Darcy
    velocity distributions in the fracture and matrix
    continua. The flow modelling results for the
    reduced fracture zone network will be compared to
    those from the full network provided by Sykes et
    al. (2004) and forwarded to OPG. This work was
    completed by Stefano.

7
Visualisation - Sub-regional Flow System
Modelling Results
  • The purpose of this element of the work program
    is to support a demonstration of the application
    of Virtual Reality (VR) Technology for site
    specific, Shield flow system interpretation and
    analysis at the 2005 NEA-AMIGO Workshop, which is
    scheduled for September 20-22 in Toronto. The VR
    demonstration will be developed by MIRARCO
    located at Laurentian University in Sudbury. With
    respect to geoscience, scientific visualization
    and VR technology provide an effective site
    characterisation tool for interpretation and
    communication of geoscientific information of
    complex 3-dimensional geometry. This technology
    is particularly useful for the integration of
    multi-disciplinary data sets necessary to
    establish spatial relationships and coincidence.
    Supporting activities will include
  • coordination with MIRARCO on the preparation of
    Sub-regional modelling grid meshes, discrete
    fracture network models and parameter input data
    sets for transfer into Gocad and the VR environ
  • work completed by Stefano and Young-Jin ongoing
    as required
  • coordinate with MIRARCO the transfer of
    predictive Sub-regional modelling results, to
    illustrate aspects of flow system evolution and
    groundwater flow system properties or
    characteristics relevant to repository siting
    and/or long-term safety
  • work completed by Stefano and Young-Jin ongoing
    as required
  • participation in a 2-day workshop at MIRARCOs
    Virtual Reality Theatre in Sudbury for the
    purpose of reviewing the Gocad-based
    representations of sub-regional modelling results
    and
  • work completed by Stefano and Young-Jin ongoing
    as required
  • participation in the AMIGO workshop, presentation
    of Sub-regional modelling strategies and results
    during the OPG session on September 20th (to be
    developed in cooperation with OPG and other
    members of the Task Force on Shield Groundwater
    Flow System Characterisation and Simulation), and
    leading the Sub-regional modelling session during
    the SciViz demonstration on the evening of
    September 21.
  • work completed by Stefano and Young-Jin ongoing
    as required

8
QA/QC work plan for UofW
9
Bruce DGR Conceptual Model
10
StratigraphicColumn
Repository Horizon
11
Sub-Regional Analysis
  • Spatial domain approximately 22 km by 20 km,
    surface to Precambrian
  • Transient analysis initial conditions include
    pressure and salinity for all layers
  • Sanford model will be used to define sub-features
    such as distribution of Cambrian, distribution of
    salt, pinnacle reefs, flow in fractures
  • Uncertainty analysis related to conceptual model
    and parameters
  • Lake Huron boundary conditions ?

12
Sub-Regional Analysis
  • Scale of wells will require soft data to define
    features of Sanford conceptual model
  • Sensitivity of flow and transport in Ordovician
    limestone to geometry and parameters of assumed
    features must be investigated. Examples
  • pinnacle reefs
  • dolomitized limestone
  • presence of salt and Cambrian
  • Bruce megablock fractures orientation and
    properties

13
Wells Drilled to Precambrian
14
B Salt (red present)
15
Wells to Cambrian and Precambrian
16
Wells to Cobourg and Precambrian
17
Rockworks Characterization
18
Rockworks Characterization
19
Rockworks 1st Order Polynomial
20
Lake Elevations
21
Boundary Conditions
22
DEM
23
Bathymetry
24
TIN for Lake Huron
25
Cases
  • 1 gradient in units below Queenston/Georgian
    Bay/Blue Mtn shale to Lake Huron 196 m at
    east, 176 at west
  • 2 gradient in units below shale away from Lake
    Huron 176 m at west, 170 m at east
    (corresponds to gradient between Bruce site and
    Lake Ontario at Hamilton)
  • Initial hydraulic properties from Golder (2003)

26
Case 1
27
Case 1
28
Case 1
29
Case 1
30
Case 2
31
Case 2
32
Case 2
33
Case 2
34
What is next?
  • Add TDS to model layers as initial condition
  • Revise Diriclet boundary conditions to
    appropriate pressure and TDS
  • Refine geologic model for layers
  • Generate issues list
  • Develop regional conceptual model and issues to
    be resolved with model
  • Develop calibration data set geochemistry,
    hydraulic (?)
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