The structure of the public radiation dose resulting from gas aerosol emissions of the experimental-demonstration energy complex incorporating the BREST-OD-300 reactor and fuel fabrication and reprocessing modules is determined. The yearly radiation dose to humans at the point of maximum ground concentration of radionuclides from design basis emissions of the energy complex is formed primarily by 3H,14C, and fission products (0.73, 1.2 2, and 0.9 μSv, respectively) through the peroral pathway as a result of the fallout during the running year of operation of the enterprises. The largest contribution to the irradiation dose is due to the emissions from the spent fuel reprocessing module – 2.33 μSv/yr – and 50% is due to 14C. The radiation dose from the emissions of the BREST-OD-300 reactor is almost completely due to 3H and 210Po (0.73 and 0.17 μSv/yr, respectively). The emissions from the fuel fabrication module have the smallest effect on the public. The dose from fission products is produced by emissions from the reprocessing module approximately in equal amounts in terms of external and internal pathways (0.47 and 0.43 μSv).
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References
L. A. Sharpan, E. I. Karpenko, and S. I. Spiridonov, “Determination of the public irradiation dose as result of atmospheric emissions from the Rostov NPP,” At. Energ., 115, No. 3, 163–166 (2013).
I. I. Kryshev and E. P. Ryazantsev, Environmental Safety of the Nuclear Power Complex of Russia, IzdAT, Moscow (2010).
I. I. Kryshev (ed.), R. M. Aleksakhin, T. G. Sazykina, et al., The Radioactivity of the Regions around NPP, IAE im. Kurchatova, Moscow (1991).
Assessment of Radioactive Discharges on Non-Human Species, Westinghouse Electric Company LLC Report UKPGW-GL-033, Rev. 2 (2011).
Yearbook of the Radiation Conditions on the Territory of Russia and Adjoining Countries, NPO Taifun, Obninsk (2016).
Sh. Kunihiko, “Assessment of radiological effects on the regional environment due to the operation of the Tokai reprocessing plant,” J. Environ. Rad., 72, 299– 322 (2004).
J. Vives i Batlle, S. Jones, and D. Copplestone, “A method for estimating 41Ar, 85,88Kr and 131m,133Xe doses to non-human biota,” J. Environ. Rad., 144, 152–161 (2015).
D. Copplestone, J. Brown, and N. Beresford, “Considerations for the integration of human and wildlife radiological assessments,” J. Radiol. Prot., 30, 283–297 (2010).
H. Vandenhove, L. Sweeck, J. Vives i Batlle, et al., “Predicting the environmental risks of radioactive discharges from Belgian nuclear power plants,” J. Environ. Rad., 126, 61–76 (2013).
Generic Models for Use in Assessing the Impact of Discharges of Radioactive Substances to the Environment, Saf. Rep. Ser. No. 19, IAEA, Vienna (2001).
P. Thompson, N.-O. Kwamena, M. Ilin, et al., “Levels of tritium in soils and vegetation near Canadian nuclear facilities releasing tritium to the atmosphere: implications for environmental models,” J. Environ. Rad., 140, 105–113 (2015).
N. G. Gusev and V. A. Belyaev, Handbook of Radioactive Emissions into the Atmosphere, Energoatomizdat, Moscow (1991), 2nd ed.
Recommended Methods of Calculating the Parameters Necessary for Developing and Establishing Norms for the Maximum Admissible Emissions of Radioactive Substances into Atmospheric Air, Safety Guidelines for Using Atomic Energy, approved by Decree of the Federal Environmental, Technological, and Atomic Oversight Agency, No. 458, Nov. 11, 2015.
K. Eckerman and J. Ryman, External Exposure to Radionuclides in Air, Water, and Soil, US Federal Guidance Rep. No. 12 (1993).
Materials for Evaluating the Environmental Effect of ODEK in the Composition of the Fabrication Module, BRESTOD-300 Reactor Installation, and SNF Refabrication and Reprocessing Modules, 0306-OVOS, VNIPIET, St. Petersburg (2013).
Emissions from the BREST-OD-300 Reactor during Normal Operation and Emergency Situations, Technical Information, NIKIET, Moscow (2016).
R. M. Aleksakhin, E. V. Spirin, V. M. Solomatin, and S. I. Spiridonov, “Some environmental aspects of the construction of experimental demonstration energy complex in Project Proryv,” At. Energ., 120, No, 6, 312–318 (2016).
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Translated from Atomnaya Energiya, Vo. 124, No. 3, pp. 169–173, March, 2018.
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Spirin, E.V., Aleksakhin, R.M. & Bazhanov, A.A. Structure of the Public Irradiation Dose During Operation of Experimental-Demonstration Power Complex Enterprises. At Energy 124, 203–209 (2018). https://doi.org/10.1007/s10512-018-0398-1
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DOI: https://doi.org/10.1007/s10512-018-0398-1