TY - JOUR
T1 - Computational and experimental prediction of dust production in pebble bed reactors-Part I
AU - Rostamian, Maziar
AU - Johnson, Gannon
AU - Hiruta, Mie
AU - Potirniche, Gabriel P.
AU - Ougouag, Abderrafi M.
AU - Cogliati, Joshua J.
AU - Tokuhiro, Akira
PY - 2013
Y1 - 2013
N2 - This paper describes the computational modeling and simulation, and experimental testing of graphite moderators in frictional contacts as anticipated in a pebble bed reactor. The potential of carbonaceous particulate generation due to frictional contact at the surface of pebbles and the ensuing entrainment and transport into the gas coolant are safety concerns at elevated temperatures under accident scenarios such as air ingress in the high temperature gas-cooled reactor. The safety concerns are due to the documented ability of carbonaceous particulates to adsorb fission products and transport them in the primary circuit of the pebble bed reactor, thus potentially giving rise to a relevant source term under accident scenarios. Here, a finite element approach is implemented to develop a nonlinear wear model in air environment. In this model, material wear coefficient is related to the changes in asperity height during wear. The present work reports a comparison between the finite element simulations and the experimental results obtained using a custom-designed tribometer. The experimental and computational results are used to estimate the quantity of nuclear grade graphite dust produced from a typical anticipated configuration. In Part II, results from a helium environment at higher temperatures and pressures are experimentally studied.
AB - This paper describes the computational modeling and simulation, and experimental testing of graphite moderators in frictional contacts as anticipated in a pebble bed reactor. The potential of carbonaceous particulate generation due to frictional contact at the surface of pebbles and the ensuing entrainment and transport into the gas coolant are safety concerns at elevated temperatures under accident scenarios such as air ingress in the high temperature gas-cooled reactor. The safety concerns are due to the documented ability of carbonaceous particulates to adsorb fission products and transport them in the primary circuit of the pebble bed reactor, thus potentially giving rise to a relevant source term under accident scenarios. Here, a finite element approach is implemented to develop a nonlinear wear model in air environment. In this model, material wear coefficient is related to the changes in asperity height during wear. The present work reports a comparison between the finite element simulations and the experimental results obtained using a custom-designed tribometer. The experimental and computational results are used to estimate the quantity of nuclear grade graphite dust produced from a typical anticipated configuration. In Part II, results from a helium environment at higher temperatures and pressures are experimentally studied.
UR - http://www.scopus.com/inward/record.url?scp=84885182448&partnerID=8YFLogxK
U2 - 10.1016/j.nucengdes.2013.04.019
DO - 10.1016/j.nucengdes.2013.04.019
M3 - Article
AN - SCOPUS:84885182448
SN - 0029-5493
VL - 263
SP - 500
EP - 508
JO - Nuclear Engineering and Design
JF - Nuclear Engineering and Design
ER -