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http://dx.doi.org/10.17946/JRST.2021.44.4.351

Analysis and Consideration of the Establishment of a Multiplexed Channel for Domestic RI Waste Nuclide Analysis  

Han, Sang-Jun (RMTech Co., Ltd.)
Lee, Hong-Yeon (RMTech Co., Ltd.)
Kim, Bo-Gil (RMTech Co., Ltd.)
An, Eun-Mi (RMTech Co., Ltd.)
Publication Information
Journal of radiological science and technology / v.44, no.4, 2021 , pp. 351-358 More about this Journal
Abstract
This research project is a program promoted to seek diversification of domestic radioactive waste analysis institutions, and seeks public development, win-win cooperation, and cooperation between the entrusted institution and the entrusted institution. Accordingly, the entrusted institution established a standard analysis procedure for establishing a quality control system for radioactivity analysis, establishing a radiation control zone, obtaining KOLAS accreditation, and performing proficiency tests, which are the performance ranges requested by the entrusted institution, and intersecting the radioactive isotope waste generated at the actual site. Verification was performed to confirm the analysis quality. In addition, facilities and equipment for radioactivity analysis were supplemented and expanded, and the basic technology foundation and technical skills were secured through securing professional technicians and education/training. It is judged that the entrusted institution will contribute to securing radiation safety through the smooth execution of treatment, disposal, and transportation through value creation and analysis of radioactive waste generated by radioactive isotope-using institutions (research institutes, hospitals, industries, etc.) by succeeding in this research project do.
Keywords
Radioactive Isotope Waste; Nuclide Aanalysis; Quality Assurance Procedure; Radiation Control Area; KOLAS;
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  • Reference
1 ISO/IEC 17025. General requirements for the competence of testing and calibration laboratories; 2005.
2 HASL-300. Tritium in water-liquid scintillation counting, 3H-04-RC; 1997.
3 HASL-300. Gamma radioassay, Ga-01-R; 1997.
4 ISO. Guide to the expression of uncertainty in measurement; 1993.
5 Cooper JA. Factors determining the ultimate detection sensitivity of Ge(Li) Gamma-ray spectrometers, pp.273-7, North Holland Publishing Co; 1970.
6 KAERI. Chemical analysis of radioactive materials, RR-4323; 2017.
7 KAERI. Fundamental researches on radiochemistry of nuclear fuel cycle, RR-4418; 2018.
8 KAERI. The Procedure for investigating the radiation environment around the KAERI, TR-4102; 2010.
9 Wallac Company. 1220 Quantulus liquid scintillation counter instrument manual; 1995.
10 Packard Instrument Company. Laboratory manual for liquid scintillation counting; 1988.
11 Jo JG, Lee SB, Nam JY, Noh EJ, Beak HW, Lee YJ, et al. Evaluation of radioactive substance and measurement of harmfulness in drinking water. Journal of Radiological Science and Technology, 2021;44(3):247-52.   DOI
12 ISO 18589-3. Measurement of radioactivity in the environment-soil-Part 3: Test method of gamma emittion radionuclides using gamma-ray spectrometry, Edition 2; 2015.
13 International Atomic Energy Agency. Classification of radioactive waste, IAEA Safety Standards Series No. GSG-1. Vienna; 2009.
14 Muramatsu Y, Uchida S, Ohmomo Y. Determination of I-129 and I-127 in soil and trace experiments on the adsorption of iodine on soil. J Radioanal Nucl Chem. 1990;138(2):377-84.   DOI
15 L'Annunziata MF. A Handbook of radioactivity analysis. San Diego Academic press; 1998.
16 ASTM. ASTM standard test method for alpha and beta activity in water by liquid scintillation counting. West Conshohocken; 2006.
17 PerkinElmer. Quantulus 1220 liquid scintillation counter instrument manual; 2004.
18 Jang ES, Gim YS, Lee SY. Marinelli beaker measurement and self absorption correction and application for various environmental samples in montecarlo simulation. Journal of Radiological Science and Technology. 2017;40(4):605-11.   DOI