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Title: Adequacy of radioiodine control and monitoring at nuclear fuels reprocessing plants

Abstract

The present backlog of irradiated reactor fuel leads to projections that no fuel out of the reactor less than 10 years need be reprocessed prior to the year 2000. The only radioiodine present in such aged fuel is /sup 129/I (half-life 1.6 x 10/sup 7/ y). The /sup 131/I initially present in the fuel decays to insignificance in the first few hundred days post-reactor. The /sup 129/I content of irradiated fuel is about 1 Ci per gigawatt-year of electricity generated (Ci/GW(e)-y). The US EPA has specified, in 40 CFR 190, a release limit for /sup 129/I of 5 mCi/GW(e)-y. Thus a retention factor (RF) of 200 for /sup 129/I at the fuel reprocessing plant (FRP) is required. Experience indicates that RF values obtained under actual FRP operating conditions can average as little as 10% of experimentally determined RF values. Therefore processes theoretically capable of achieving RF values of up to 10/sup 4/ have been investigated. The US EPA has also specified in 40 CFR 90 a thyroid dose limit of 75 mrem/y for a member of the general public. This dose limit could be readily met at a typical FRP site with an RF value of about 10 or less.more » Therefore, the limit of 5 mCi/GW(e)-y is more restrictive than the thyroid dose limit for /sup 129/I. The absence of /sup 131/I in effluents from processing of aged fuels makes analysis of /sup 129/I somewhat easier. However, in-line, real-time monitoring for /sup 129/I in FRP gas streams is currently not feasible. Moisture, chemicals, and other radioactive fission products interfere with in-plant measurements. Samples collected over several days must be taken to a laboratory for /sup 129/I analysis. Measurement techniques currently in use or under investigation include neutron activation analysis, scintillation counting, mass spectroscopy, and gas chromatography coupled with electron capture detection. 26 references, 3 figures, 7 tables.« less

Authors:
; ;
Publication Date:
Research Org.:
Pacific Northwest National Lab. (PNNL), Richland, WA (United States)
OSTI Identifier:
6993477
Report Number(s):
PNL-5108
ON: DE84013311
DOE Contract Number:  
AC06-76RL01830
Resource Type:
Technical Report
Country of Publication:
United States
Language:
English
Subject:
12 MANAGEMENT OF RADIOACTIVE AND NON-RADIOACTIVE WASTES FROM NUCLEAR FACILITIES; 11 NUCLEAR FUEL CYCLE AND FUEL MATERIALS; FUEL REPROCESSING PLANTS; OFF-GAS SYSTEMS; IODINE 129; MONITORING; IODINE 131; RADIOACTIVE WASTE PROCESSING; BETA DECAY RADIOISOTOPES; BETA-MINUS DECAY RADIOISOTOPES; DAYS LIVING RADIOISOTOPES; INTERMEDIATE MASS NUCLEI; INTERNAL CONVERSION RADIOISOTOPES; IODINE ISOTOPES; ISOTOPES; MANAGEMENT; NUCLEAR FACILITIES; NUCLEI; ODD-EVEN NUCLEI; PROCESSING; RADIOISOTOPES; WASTE MANAGEMENT; WASTE PROCESSING; YEARS LIVING RADIOISOTOPES; 052001* - Nuclear Fuels- Waste Processing; 050800 - Nuclear Fuels- Spent Fuels Reprocessing

Citation Formats

Scheele, R D, Burger, L L, and Soldat, J K. Adequacy of radioiodine control and monitoring at nuclear fuels reprocessing plants. United States: N. p., 1984. Web. doi:10.2172/6993477.
Scheele, R D, Burger, L L, & Soldat, J K. Adequacy of radioiodine control and monitoring at nuclear fuels reprocessing plants. United States. https://doi.org/10.2172/6993477
Scheele, R D, Burger, L L, and Soldat, J K. 1984. "Adequacy of radioiodine control and monitoring at nuclear fuels reprocessing plants". United States. https://doi.org/10.2172/6993477. https://www.osti.gov/servlets/purl/6993477.
@article{osti_6993477,
title = {Adequacy of radioiodine control and monitoring at nuclear fuels reprocessing plants},
author = {Scheele, R D and Burger, L L and Soldat, J K},
abstractNote = {The present backlog of irradiated reactor fuel leads to projections that no fuel out of the reactor less than 10 years need be reprocessed prior to the year 2000. The only radioiodine present in such aged fuel is /sup 129/I (half-life 1.6 x 10/sup 7/ y). The /sup 131/I initially present in the fuel decays to insignificance in the first few hundred days post-reactor. The /sup 129/I content of irradiated fuel is about 1 Ci per gigawatt-year of electricity generated (Ci/GW(e)-y). The US EPA has specified, in 40 CFR 190, a release limit for /sup 129/I of 5 mCi/GW(e)-y. Thus a retention factor (RF) of 200 for /sup 129/I at the fuel reprocessing plant (FRP) is required. Experience indicates that RF values obtained under actual FRP operating conditions can average as little as 10% of experimentally determined RF values. Therefore processes theoretically capable of achieving RF values of up to 10/sup 4/ have been investigated. The US EPA has also specified in 40 CFR 90 a thyroid dose limit of 75 mrem/y for a member of the general public. This dose limit could be readily met at a typical FRP site with an RF value of about 10 or less. Therefore, the limit of 5 mCi/GW(e)-y is more restrictive than the thyroid dose limit for /sup 129/I. The absence of /sup 131/I in effluents from processing of aged fuels makes analysis of /sup 129/I somewhat easier. However, in-line, real-time monitoring for /sup 129/I in FRP gas streams is currently not feasible. Moisture, chemicals, and other radioactive fission products interfere with in-plant measurements. Samples collected over several days must be taken to a laboratory for /sup 129/I analysis. Measurement techniques currently in use or under investigation include neutron activation analysis, scintillation counting, mass spectroscopy, and gas chromatography coupled with electron capture detection. 26 references, 3 figures, 7 tables.},
doi = {10.2172/6993477},
url = {https://www.osti.gov/biblio/6993477}, journal = {},
number = ,
volume = ,
place = {United States},
year = {Fri Jun 01 00:00:00 EDT 1984},
month = {Fri Jun 01 00:00:00 EDT 1984}
}