Investigation on Suitability of Argillaceous Rocks of Vindhyan Super Group as Host Rock for Deep Geological Repository using Thermal Analysis

T.K. Pal; R.K. Bajpai; A. Acharya; R. S. Bhatia; D. Datta

doi:10.51710/jias.v38i1.158

Authors

T.K. Pal Technology Development Division, BARC
R.K. Bajpai Technology Development Division, BARC
A. Acharya Technology Development Division, BARC
R. S. Bhatia Technology Development Division, BARC
D. Datta Radiological Physics and Advisory Division, BARC

DOI:

https://doi.org/10.51710/jias.v38i1.158

Abstract

Argillaceous rocks are being considered as a potential host rock for deep geological repository (DGR) for hosting vitrified high level radioactive waste canisters by many countries worldwide. Numerical simulation of thermal evolution in the repository environment is an important study for the long term safety performance assessment of a DGR. In this study, thermal dissipation in the near field area of a conceptual repository in Ganurgarh shales from Bhander Group of Vindhyan Super Group, which is the thickest sedimentary succession of India, has been simulated using commercial software FLAC3D, which solves the governing heat diffusion equation using explicit and implicit finite difference methods. Model parameters like thermal conductivity, specific heat, density of the shales are generated in the laboratory. From the analysis of time dependent temperature profile it is observed that maximum temperature of 70.5^oC is attained at canister surface after 22 years of heating for a heat loadings of 500 W/overpack. Since the maximum temperature is well below the permissible limit of temperature (100^oC), the heat load of the source is increased to 700 W/overpack and in this case the simulated value of maximum temperature is 93^oC. Maximum temperatures at other locations within the near field region are also within the permissible limit.

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