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On thermohydrologic conditions near high-level nuclear wastes emplaced in partially saturated fractured tuff. 1. Simulation studies with explicit consideration of fracture effects

Journal Article · · Water Resources Research
DOI:https://doi.org/10.1029/89WR03753· OSTI ID:138184
; ;  [1]
  1. Lawrence Berkeley Lab., CA (USA)
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The authors have performed modeling studies on the simultaneous transport of heat, liquid water, vapor, and air in partially saturated, fractured porous rock. Formation parameters were chosen as representative of the potential nuclear waste repository site in the Topopah Spring unit of the Yucca Mountain tuffs. The numerical simulator used for the flow calculations takes into account most of the physical effects believed to be important in multiphase fluid and heat flow. The authors model a region around an infinite linear string of nuclear waste canisters, taking into account both the discrete fractures and the porous matrix. Thermohydrologic conditions in the vicinity of the waste packages are found to depend strongly on relative permeability and capillary pressure characteristics of the fractures, which are unknown at the present time. If liquid held on the rough walls of drained fractures is assumed to be mobile, strong heat pipe effects are predicted. Under these conditions the host rock will remain in two-phase conditions right up to the emplacement hole, and formation temperatures will peak near 100C. If it is assumed that liquid cannot move along drained fractures, the region surrounding the waste packages is predicted to dry up, and formation temperatures will rise beyond 200C. A substantial fraction of waste heat can be removed if emplacement holes are left open and ventilated, as opposed to backfilled and sealed emplacement conditions. Comparing model predictions with observations from in situ heater experiments reported by Zimmerman and coworkers, some intriguing similarities are noted.

DOE Contract Number:
AC03-76SF00098
OSTI ID:
138184
Journal Information:
Water Resources Research, Journal Name: Water Resources Research Journal Issue: 6 Vol. 26; ISSN WRERAQ; ISSN 0043-1397
Country of Publication:
United States
Language:
English

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Related Subjects

05 NUCLEAR FUELS
ENVIRONMENTAL TRANSPORT
FLUID FLOW
GEOLOGIC FRACTURES
HEAT FLOW
HIGH-LEVEL RADIOACTIVE WASTES
HYDROLOGY
RADIOACTIVE WASTE DISPOSAL
SIMULATION
UNDERGROUND DISPOSAL
YUCCA MOUNTAIN
Yucca Mountain Project