EBS Radionuclide Transport Abstraction
Attachment | Size |
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ANL-WIS-PA-000001 REV 03.pdf (12.98 MB) | 12.98 MB |
ANL-WIS-PA-000001 REV 03 ERD 01.pdf (9.29 MB) | 9.29 MB |
ANL-WIS-PA-000001 REV 03 ERD 02.pdf (4.43 MB) | 4.43 MB |
ANL-WIS-PA-000001 REV 03 ERD 03.pdf (5.84 MB) | 5.84 MB |
The purpose of this report is to develop and analyze the Engineered Barrier System (EBS) Radionuclide Transport Abstraction Model, consistent with Level I and Level II model validation, as identified in Technical Work Plan for: Near-Field Environment: Engineered Barrier System: Radionuclide Transport Abstraction Model Report (BSC 2006 [DIRS 177739]). The EBS Radionuclide Transport Abstraction (or RTA) is the conceptual model used in the Total System Performance Assessment (TSPA) to determine the rate of radionuclide releases from the EBS to the unsaturated zone (UZ).
The RTA conceptual model consists of two main components: a flow model and a transport model. Both models are developed mathematically from first principles in order to show explicitly what assumptions, simplifications, and approximations are incorporated into the models used in the TSPA.
The flow model defines the pathways for water flow in the EBS and specifies how the flow rate is computed in each pathway. Input to this model includes the seepage flux into a drift. The seepage flux is potentially split by the drip shield, with some (or all) of the flux being diverted by the drip shield and some passing through breaches in the drip shield that might result from corrosion or seismic damage. The flux through drip shield breaches is potentially split by the waste package, with some (or all) of the flux being diverted by the waste package and some passing through waste package breaches that might result from corrosion or seismic damage. Neither the drip shield nor the waste package survives an igneous intrusion, so the flux splitting submodel is not used in the igneous scenario class. The flow model is validated in a critical review, as specified in SCI-PRO-006, Models. The drip shield and waste package flux splitting algorithms are developed and validated using experimental data.