An analysis of nuclear fuel burnup in the AGR-1 TRISO fuel experiment using gamma spectrometry, mass spectrometry, and computational simulation techniques

•The burnup of irradiated AGR-1 TRISO fuel was analyzed using gamma spectrometry.•The burnup of irradiated AGR-1 TRISO fuel was also analyzed using mass spectrometry.•Agreement between experimental results and neutron physics simulations was excellent. AGR-1 was the first in a series of experiments...

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Veröffentlicht in:Nuclear engineering and design 2014-10, Vol.278 (C), p.395-405
Hauptverfasser: Harp, Jason M., Demkowicz, Paul A., Winston, Philip L., Sterbentz, James W.
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Sprache:eng
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Zusammenfassung:•The burnup of irradiated AGR-1 TRISO fuel was analyzed using gamma spectrometry.•The burnup of irradiated AGR-1 TRISO fuel was also analyzed using mass spectrometry.•Agreement between experimental results and neutron physics simulations was excellent. AGR-1 was the first in a series of experiments designed to test US TRISO fuel under high temperature gas-cooled reactor irradiation conditions. This experiment was irradiated in the Advanced Test Reactor (ATR) at Idaho National Laboratory (INL) and is currently undergoing post-irradiation examination (PIE) at INL and Oak Ridge National Laboratory. One component of the AGR-1 PIE is the experimental evaluation of the burnup of the fuel by two separate techniques. Gamma spectrometry was used to non-destructively evaluate the burnup of all 72 of the TRISO fuel compacts that comprised the AGR-1 experiment. Two methods for evaluating burnup by gamma spectrometry were developed, one based on the Cs-137 activity and the other based on the ratio of Cs-134 and Cs-137 activities. Burnup values determined from both methods compared well with the values predicted from simulations. The highest measured burnup was 20.1% FIMA (fissions per initial heavy metal atom) for the direct method and 20.0% FIMA for the ratio method (compared to 19.56% FIMA from simulations). An advantage of the ratio method is that the burnup of the cylindrical fuel compacts can be determined in small (2.5mm) axial increments and an axial burnup profile can be produced. Destructive chemical analysis by inductively coupled mass spectrometry (ICP-MS) was then performed on selected compacts that were representative of the expected range of fuel burnups in the experiment to compare with the burnup values determined by gamma spectrometry. The compacts analyzed by mass spectrometry had a burnup range of 19.3% FIMA to 10.7% FIMA. The mass spectrometry evaluation of burnup for the four compacts agreed well with the gamma spectrometry burnup evaluations and the expected burnup from simulation. For all four compacts analyzed by mass spectrometry, the maximum range in the three experimentally determined values and the predicted value was 6% or less. The results confirm the accuracy of the nondestructive burnup evaluation from gamma spectrometry for TRISO fuel compacts across a burnup range of approximately 10–20% FIMA and also validate the approach used in the physics simulation of the AGR-1 experiment.
ISSN:0029-5493
1872-759X
DOI:10.1016/j.nucengdes.2014.07.041