Shielding evaluation of neutron generator hall by Monte Carlo simulations

Thilagam Lakshminarayanan

doi:10.15392/bjrs.v5i1.221

Authors

Thilagam Lakshminarayanan Safety Research Institute Atomic Energy Regulatory Board India

DOI:

https://doi.org/10.15392/bjrs.v5i1.221

Keywords:

Monte Carlo (MC) codes, NCRP-51 methodology, Neutron & Capture gamma dose rates

Abstract

A shielded hall was constructed for accommodating a D-D, D-T or D-Be based pulsed neutron generator (NG) with 4π yield of 10⁹ n/s. The neutron shield design of the facility was optimized using NCRP-51 methodology such that the total dose rates outside the hall areas are well below the regulatory limit for full occupancy criterion (1 µSv/h). However, the total dose rates at roof top, cooling room trench exit and labyrinth exit were found to be above this limit for the optimized design. Hence, additional neutron shielding arrangements were proposed for cooling room trench and labyrinth exits. The roof top was made inaccessible. The present study is an attempt to evaluate the neutron and associated capture gamma transport through the bulk shields for the complete geometry and materials of the NG-Hall using Monte Carlo (MC) codes MCNP and FLUKA. The neutron source terms of D-D, D-T and D-Be reactions are considered in the simulations. The effect of additional shielding proposed has been demonstrated through the simulations carried out with the consideration of the additional shielding for D-Be neutron source term. The results MC simulations using two different codes are found to be consistent with each other for neutron dose rate estimates. However, deviation up to 28% is noted between these two codes at few locations for capture gamma dose rate estimates. Overall, the dose rates estimated by MC simulations including additional shields shows that all the locations surrounding the hall satisfy the full occupancy criteria for all three types of sources. Additionally, the dose rates due to direct transmission of primary neutrons estimated by FLUKA are compared with the values calculated using the formula given in NCRP-51 which shows deviations up to 50% with each other. The details of MC simulations and NCRP-51 methodology for the estimation of primary neutron dose rate along with the results are presented in this paper.

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Author Biography

Thilagam Lakshminarayanan, Safety Research Institute Atomic Energy Regulatory Board India

Dr.L.Thilagam

Technical Officer (E)

Atomic Energy Regulatory Board

India

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