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Field tests for performance evaluation of a new spent-fuel verification system in heavy water reactor
The optical fiber-based measurement system has been utilized for inspecting CANDU-type spent fuel at the Wolsung site in South Korea under the nuclear safeguards of the International Atomic Energy Agency (IAEA). In our previous studies, we developed a new spent-fuel verification system to address is...
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Published in: | Journal of instrumentation 2024-03, Vol.19 (3), p.C03057 |
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Main Authors: | , , , , |
Format: | Article |
Language: | English |
Subjects: | |
Citations: | Items that this one cites |
Online Access: | Get full text |
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Summary: | The optical fiber-based measurement system has been utilized for inspecting CANDU-type
spent fuel at the Wolsung site in South Korea under the nuclear safeguards of the International
Atomic Energy Agency (IAEA). In our previous studies, we developed a new spent-fuel verification
system to address issues of the existing instrument. While our prior work primarily focused on
equipment development, we had not yet conducted comprehensive field tests to assess its
performance. Recently, we conducted field tests at the Wolsung Unit 4 to thoroughly evaluate the
newly developed spent-fuel verification system's performance. This paper discusses the results of
these field tests, with a focus on signal sensitivity, the system's capability to distinguish
neighboring spent-fuel bundles, and the optical fiber background signals. Additionally, we
conducted experiments to assess how different scintillation materials impact the system's
performance, including p-terphenyl organic scintillator, PVT plastic scintillator, and lithium
glass scintillator. The experimental results demonstrated that the new instrument equipped with
the p-terphenyl organic scintillator outperformed the existing system. The p-terphenyl
scintillator emerged as the superior choice among the three radiation scintillators. Signals that
were previously undetectable using the Li glass scintillator were observed in the signals obtained
with the p-terphenyl and PVT plastic scintillators. The remarkable performance of the new
verification instrument is attributed mainly to the p-terphenyl's high light output and low decay
time. The newly developed verification system is expected to streamline IAEA safeguards inspection
efforts, reducing both time and the burden on nuclear operators. This report represents the first
successful application of the p-terphenyl scintillator as a radiation detector in a wet spent fuel
pool. The experimental findings presented in this paper are anticipated to be valuable for
researchers working on radiation detectors suitable for high radiation environments in water. |
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ISSN: | 1748-0221 1748-0221 |
DOI: | 10.1088/1748-0221/19/03/C03057 |