DOSE RATE IN A DEACTIVATED URANIUM MINE

Authors

  • Wagner De Souza Pereira Indústrias Nucleares do Brasil; Universidade Veiga de Almeida Curso de Pós-Graduação em Ciências do Meio Ambiente
  • Alphonse Kelecom Universidade Federal Fluminense
  • Ademir Xavier da Silva UFRJ
  • José Marquez Lopes Universidade Federal do Rio de Janeiro
  • Alessander Sá do Carmo Universidade Federal do Rio de Janeiro
  • Ayandra Oliveira Dias universidade Veiga de Almeida
  • Carlos Eduardo Cogo Pinto Universidade Veiga de Almeida

DOI:

https://doi.org/10.15392/bjrs.v7i2B.523

Keywords:

Dose Rate, Uranium Mine, radioprotection

Abstract

The Ore Treatment Unit is a deactivated uranium mine and milling situated in Caldas, MG, BR. Although disabled, there are still areas considered controlled and supervised from the radiological point of view. In these areas, it is necessary to keep an occupational monitoring program to ensure the workers' safety and to prevent the dispersion of radioactive material. For area monitoring, the dose rate, in µSv∙h-1, was measured with Geiger Müller (GM) area monitors or personal electronic monitors type GM and thermoluminescence dosimetry (TLD), in mSv∙month-1, along the years 2013 to 2016. For area monitoring, 577 samples were recorded; for personal dosimeters monitoring, 2,656; and for TLD monitoring type, 5,657. The area monitoring showed a mean dose rate of 6.42 µSv∙h-1 associated to a standard deviation of 48 µSv∙h-1 with a maximum recorded value of 685 µSv∙h-1. 96 % of the samples were below the derived limit per hour for workers (10 µSv∙h-1). For the personal electronic monitoring, the average of the data sampled was 15.86 µSv∙h-1, associated to a standard deviation of 61.74 µSv∙h-1. 80 % of the samples were below the derived limit and the maximum recorded was 1,220 µSv∙h-1. Finally, the TLD showed a mean of 0.01 mSv∙h-1 (TLD detection limit is 0.2 mSv∙month-1 equivalent to 0.28 µSv∙h-1), associated to a standard deviation of 0.08 mSv∙h-1. 98% of the registered values were below 0.2 mSv∙month-1 and less than 2 % of the measurements had values above the limit of detection. The samples show areas with low risk of external exposure, as can be seen by the TLD evaluation. Specific areas with greater risk of contamination have already been identified, as well as operations at higher risks. In these cases, the use of the individual electronic dosimeter is justified for a more effective monitoring. Radioprotection identified all risks and was able to extend individual electronic monitoring to all risk operations, even with the use of the TLD.

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Author Biographies

  • Wagner De Souza Pereira, Indústrias Nucleares do Brasil; Universidade Veiga de Almeida Curso de Pós-Graduação em Ciências do Meio Ambiente
    Biológo UFRRJ), com especialização em ciências do Ambiente (UFRRJ), especialização em biologia marinha (Radioecologia marinha - UFF), mestrado em biomar (Radioecologia ,Marinha - UFF) doutor em Biomar (radioproteção ambiental). Supervisor de radioproteção nas práticas de: 1) Mineração e beneficiamento físico, químico e metalúrgicode minérios com U ou Th associados, 2) Mineração de Beneficiamento físico e químico de urânio e/ou tório, gerencia de rejeitos radioativos, perfilagem de poços de petróleo e medidores nucleares. registrado para uso de pequenas quantidades de radioisótopos em pesquisa. Atua no treinamento em radioproteção e formação de supervisores. avaliação de dose via análise de excretas. monitoração radiologica ambiental associada a minas de urânio. monitoração ocupacional em minas de urânio. Radioproteção ocupacional e ambiental, radioecologia.modelagem de cálculo de dose, de dispersão ambiental de radionuclídeos. Atualmente trabalho no laboratório de monitoração ambiental, no serviço de radioproteção da Unidade de Tratamento de Minérios da INB.
  • Carlos Eduardo Cogo Pinto, Universidade Veiga de Almeida
    Licenciado em Quimica, M. Sc em Meio Ambiente, Mestardo Profissional em Meio Ambiente - MPCA - UVA

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Published

2019-06-25

Issue

Vol. 7 No. 2B (Suppl.) (2019)

Section

XX Meeting on Nuclear Reactor Physics and Thermal Hydraulics (XX ENFIR)

License

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How to Cite

DOSE RATE IN A DEACTIVATED URANIUM MINE. Brazilian Journal of Radiation Sciences, Rio de Janeiro, Brazil, v. 7, n. 2B (Suppl.), 2019. DOI: 10.15392/bjrs.v7i2B.523. Disponível em: https://www.bjrs.org.br/revista/index.php/REVISTA/article/view/523.. Acesso em: 3 may. 2024.
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