The annual occupational doses for workers at the Ghana Research Reactor-1 facility were assessed for the period 2018-2021. The dose records of monitored staff were retrieved and analysis done for dose distribution and collective effective doses. Thermoluminiscent dosimeters were used to monitor the occupational exposures. The dosimeters were evaluated for the cumulative radiation dose levels using the Harshaw 6600 TLD reader system. Annual dose of 1.52 mSv/year was the maximum acquired by an individual. An annual average effective dose range of 0.20-1.36 mSv was determined for all workers. The annual total collective effective dose was established to be in the range of 0.40-10.08 man-Sv. The 20 mSv annual limit for occupational exposure was not exceeded for monitored workers. The assessment shows that the GHARR-1 facility, in terms of radiation health effects, is a favorable environment for workers since exposures are mostly below occupational exposure limit.
Download full-text PDF |
Source |
|---|---|
| http://dx.doi.org/10.1177/10482911241259515 | DOI Listing |
Publication Analysis
Top Keywords
Similar Publications
Assessment of Occupational Radiation Exposures at Ghana Research Reactor-1 Facility.
New Solut
August 2024
Radiation Protection Institute, Ghana Atomic Energy Commission, Accra, Ghana.
The annual occupational doses for workers at the Ghana Research Reactor-1 facility were assessed for the period 2018-2021. The dose records of monitored staff were retrieved and analysis done for dose distribution and collective effective doses. Thermoluminiscent dosimeters were used to monitor the occupational exposures.
View Article and Find Full Text PDFAssessment of radiological consequence of a hypothetical accident at the Ghana Research Reactor-1 facility based on terrorist attack.
Sci Prog
October 2021
Department of Nuclear Engineering, University of Ghana, Graduate School of Nuclear and Allied Sciences, Accra, Ghana.
The International Atomic Energy Agency defines a nuclear and radiation accident as an occurrence that leads to the release of radiation causing significant consequences to people, the environment, or the facility. During such an event involving a nuclear reactor, the reactor core is a critical component which when damaged, will lead to the release of significant amounts of radionuclides. Assessment of the radiation effect that emanates from reactor accidents is very paramount when it comes to the safety of people and the environment; whether or not the released radiation causes an exposure rate above the recommended threshold nuclear reactor safety.
View Article and Find Full Text PDFFuel burnup calculation of Ghana MNSR using ORIGEN2 and REBUS3 codes.
Appl Radiat Isot
October 2013
National Nuclear Research Institute, Ghana Atomic energy Commission, P.O. Box LG80, Accra, Ghana.
Ghana Research Reactor-1 core is to be converted from HEU fuel to LEU fuel in the near future and managing the spent nuclear fuel is very important. A fuel depletion analysis of the GHARR-1 core was performed using ORIGEN2 and REBUS3 codes to estimate the isotopic inventory at end-of-cycle in order to help in the design of an appropriate spent fuel cask. The results obtained for both codes were consistent for U-235 burnup weight percent and Pu-239 build up as a result of burnup.
View Article and Find Full Text PDFCharacterization of low power research reactor neutrons for the validation of k(0)-INAA standardization based on k(0)-IAEA software.
Appl Radiat Isot
September 2013
Nuclear Reactors Research Centre, National Nuclear Research Institute, Ghana Atomic Energy Commission, Box LG 80, Legon-Accra, Ghana.
Channel Bsite2 of Ghana research reactor-1 has been characterized for k0-INAA application. Cadmium ratio and bare multi-monitor were used to determine flux parameters using 0.1%Au-Al, Fe, and Zr wire as flux monitors.
View Article and Find Full Text PDFDesign of boron carbide-shielded irradiation channel of the outer irradiation channel of the Ghana Research Reactor-1 using MCNP.
Appl Radiat Isot
January 2011
Ghana Atomic Energy Commission, National Nuclear Research Institute, P.O. Box LG80, Legon, Ghana.
The MCNP model for the Ghana Research Reactor-1 was redesigned to incorporate a boron carbide-shielded irradiation channel in one of the outer irradiation channels. Extensive investigations were made before arriving at the final design of only one boron carbide covered outer irradiation channel; as all the other designs that were considered did not give desirable results of neutronic performance. The concept of redesigning a new MCNP model, which has a boron carbide-shielded channel is to equip the Ghana Research Reactor-1 with the means of performing efficient epithermal neutron activation analysis.
View Article and Find Full Text PDFWant AI Summaries of new PubMed Abstracts delivered to your In-box?
Enter search terms and have AI summaries delivered each week - change queries or unsubscribe any time!