Analysis of the Efficiency of Russian and International Methodologies of Personal Protection Equipment Shielding Evaluation in Various Conditions of Exposure to Industrial Frequency Electric Fields


Annotation:

Electromagnetic fields are a natural physical factor of the environment; however, the development of technologies facilitates the increase of anthropogenic levels of impact on humans. In a production environment, the proximity of live parts of high- and extra-high-voltage electric installations to workplaces causes the generation of electric and magnetic fields that are considered harmful occupational factors.

Personnel’s attendance in the areas where the excess of industrial frequency electric fields varies from 5 kV/m to 25 kV/m is regulated in the Russian Federation by restricting the work shift duration; however, such an approach to ensuring the occupational safety can be unprofitable and sometimes unfeasible, which requires the use of personal protection equipment. The shielding coefficient is the main parameter of personal protection equipment used against industrial frequency electric fields that indicates the degree of electric field intensity attenuation under the suit compared with external exposure.

The main protective properties of shielding shunt sets have been evaluated based on using standard personal protection equipment EP-4 (0) in various configurations.

Industrial frequency electric field strength values under the suit have been evaluated as well as the current flowing through the protective suit and an electrically conductive mannequin using an industrial frequency high-voltage test setup to imitate a workplace of electricians in homogenous and non-homogenous electric fields.

The study dedicated to the evaluation of protective properties of personal protection equipment used against industrial frequency electric fields by Russian and international methodologies has confirmed the efficiency of various sets (coverall, jacket and half-overall, jacket and trousers) for various production conditions. The analysis has revealed a higher sensitivity of the Russian evaluation methodology for the worst-case conditions when a human attends a homogenous electric field and substantiated the potential use of the sets without using separate elements for different jobs, including the jobs under voltages up to 220 kV.

References:
1. SanPiN 1.2.3685—21. Hygienic standards and requirements for ensuring safety and (or) harmlessness of environmental factors for a human. Available at: https://docs.cntd.ru/document/573500115?ysclid=lxubctcky0787814172 (accessed: April 05, 2024). (In Russ.).
2. Extremely Low Frequency Fields (Environmental Health Criteria; 238). Available at: https://inchem.org/documents/ehc/ehc/ehc238.pdf (accessed: April 05, 2024).
3. Sturman V.I., Loginovskaya A.N. Research of Spatial Distribution of Electromagnetic Fields of Industrial Frequency in the Central Part of Astrakhan. Astrakhanskiy vestnik ekologicheskogo obrazovaniya = Astrakhan Bulletin of Ecological Education. 2023. № 4 (76). pp. 59–67. (In Russ.). DOI: 10.36698/2304-5957-2023-4-59-67
4. Kislyakova A.A., Kuzmina L.P., Khotuleva A.G., Bezrukavnikova L.M. Markers of adipokine metabolism and hormonal-metabolic disorders in workers exposed to electric and magnetic fields of industrial frequency. Meditsina truda i promyshlennaya ekologiya = Russian Journal of Occupational Health and Industrial Ecology. 2023. Vol. 63. № 5. pp. 292–299. (In Russ.). DOI: 10.31089/1026-9428-2023-63-5-292-299
5. Sidorov A.I., Okrainskaya I.S., Nomokonova O.V. The Risk Assessment of Electric Field Adverse Effect to Maintenance Personnei Near Electric Installations of Superhigh Voltage. Izvestiya vysshikh uchebnykh zavedeniy. Problemy energetiki = Power engineering: research, equipment, technology. 2012. № 1-2. pp. 107–119. (In Russ.).
6. Sidorov A.I. Zakirova A.R. Method of Logical-Probabilistic Modeling of EMF Energy Characteristics Affecting Personnel. Bezopasnost zhiznedeyatelnosti = Life Safety. 2023. № 12 (276). pp. 21–26. (In Russ.).
7. Markelenkova N.A., Smirnova V.A. Assessment of professional risks of non-ionizing radiation in step-down substation. Novye gorizonty: VIII nauch.-prakt. konf. s mezhdunarodnym uchastiem. Sbornik materialov i dokladov (New Horizons: the 8th Scientific and Practical Conference with international participation. Collection of proceedings and presentations). Bryansk: Bryanskiy gosudarstvennyy tekhnicheskiy universitet, 2021. pp. 998–1002. (In Russ.).
8. Abdreshov Sh.A., Makhimova A.M., Imangalieva A.K., Baykezheeva A.S. Measures and technical equipment to protect personnel and environment against electromagnetic radiations. Internauka = Internauka. 2021. № 23-2 (199). pp. 6–10. (In Russ.).
9. Trubetskov A.D., Makhonko M.N., Shkrobova N.V., Shelekhova T.V. Problems of using personal protective equipment in modern conditions. Meditsina truda i promyshlennaya ekologiya = Russian Journal of Occupational Health and Industrial Ecology. 2023. № 63 (5). pp. 336–343. (In Russ.). DOI: 10.31089/1026-9428-2023-63-5-336-343
10. Dzhakhongiri A., Rakhmatuloev A.Z., Sharipov S.K., Safaralizoda B.S. A Method for the Protection of Personnel Engaged in the Maintenance of Overhead Lines with a Voltage of ± 500 Kv Has Been Proposed. Vestnik Bokhtarskogo gosudarstvennogo universiteta imeni Nosira Khusrava. Seriya estestvennykh nauk = Bulletin of Bokhtar State University named after NOSIRI KHUSRAV (scientific journal). Series of Natural Sciences. 2022. № 2-1 (96). pp. 46–49. (In Russ.).
11. Pirkkalainen H., Elovaara J.A., Korpinen L. Decreasing the extremely low-frequency electric field exposure with a Faraday cage during work tasks from a man hoist at a 400 kV substation. Progress in Electromagnetics Research M. 2016. Vol. 48. pp. 55–66. DOI: 10.2528/PIERM16021501
12. Göcsei G., Berta I.S., Németh B. Safety Considerations Regarding to the Shielding of Electric Fields During High Voltage Live-line Maintenance. Acta Technica Jaurinensis. 2015. Vol. 8. № 2. pp. 153–164. DOI: 10.14513/actatechjaur.v8.n2.368
13. Zhukov A.N. Improving OSHMS in Rosset FSK EES, implemented methodologies, and results. Control indices of OSHMS efficiency. Elektroenergiya. Peredacha i raspredelenie = Electric power. Transmission and distribution. 2020. № S1 (16). pp. 22–25. (In Russ.).
14. GOST 12.4.172—2019. Occupational safety standards system. Personal protective means from power frequency electric fields. Personal screening suit. General technical requirements. Test methods. Available at: https://docs.cntd.ru/document/1200167493?ysclid=lxufypdjc4488172942 (accessed: April 05, 2024). (In Russ.).
15. IEC 60895—2020. Live working — Conductive clothing. Geneva, 2020. 139 p.
16. Perov S.Yu., Konshina T.A., Makarova-Zemlyanskaya E.N. Improvement of requirements for power frequency electric field personal protective equipment. Meditsina truda i promyshlennaya ekologiya = Russian Journal of Occupational Health and Industrial Ecology. 2019. Vol. 59. № 9. pp. 718–719. (In Russ.). DOI: 10.31089/1026-9428-2019-59-9-718-719
DOI: 10.24000/0409-2961-2024-7-41-46
Year: 2024
Issue num: July
Keywords : personal protective equipment industrial frequency electric fields shielding coefficient
Authors:
  • Perov S.Yu.
    perov@irioh.ru, Dr. Sci. (Biol.), Laboratory Head, Izmerov Research Institute of Occupational Health, Moscow, Russian Federation; Assoc. Prof. of Department, Russian University of Transport (MIIT), Moscow, Russian Federation
  • Makarova-Zemlyanskaya E.N.
    Cand. Sci. (Med.), Assoc. Prof., Russian University of Transport (MIIT), Moscow, Russian Federation
  • Narusova E.Yu.
    Cand. Sci. (Eng.), Assoc. Prof., Head of the Department, Russian University of Transport (MIIT), Moscow, Russian Federation
  • Dremin A.I.
    Junior Researcher, Izmerov Research Institute of Occupational Health, Moscow, Russian Federation