Study of Low Frequency Magnetic Field of Indoor Distribution Substations

David V., Lunca E., Pavel I., Automatic Monitoring for the Magnetic Fields with the Detection and Characterization of Transient Fields. Patent applications ROBOPI 8/2019. Search in Google Scholar

David V., Pavel I., Lunca E., A method for estimating the magnetic fields generated by the overhead power lines, 11th International Conference and Exposition on Electrical and Power Engineering (EPE), 2020, Iasi, Romania, 20, 662-667. Search in Google Scholar

Hossam_Eldin A., Farag A., Madi I., Karawia H., Extremely Low Frequency Magnetic Field Survey in Indoor Distribution Substation in Egypt, 45th International Universities Power Engineering Conference UPEC, 2010, Cardiff, UK. Search in Google Scholar

Huss A., Spoerri A., Egger M., Kromhout H., Vermeulen R., Occupational extremely low frequency magnetic fields (ELF - MF) exposure and hematolymphopoietic cancers—Swiss National Cohort analysis and updated meta-analysis, Environ Res 164, 467-474 (2018). Search in Google Scholar

Keikko T., Paakkonen R., Kannala S., Seesvuori R., Valkealahti S., Magnetic Field Risk Evaluation of Workers in Indoor Distribution Substations, 20th International Conference on Electricity Distribution, 2009, Prague, Czech Republic. Search in Google Scholar

Koeman T., Brandt P.A., Slottje P., Schouten L.J., Goldbohm A., Kromhout H., Vermeulen R., Occupational extremely low-frequency magnetic field exposure and selected cancer outcomes in a prospective Dutch cohort, Cancer Causes Control, 25, 203-214 (2014). Search in Google Scholar

Konstantinoudis G., Kreis C., Ammann R.A., Niggli F., Kuehni C.E., Spycher B.D., Spatial clustering of childhood cancers in Switzerland: a nationwide Study, Springer International Publishing AG, part of Springer Nature 2018. Search in Google Scholar

Kuusiluorna S., Keikko T., Korpinen L., Magnetic Field Disturbances of Indoor MV/LV Substations in Finland, IEEE/PES Transmission and Distribution Conference and Exhibition, 2002, Yokohama, Japan. Search in Google Scholar

Mariscotti A., A magnetic field probe with MHz Bandwidth and 7 decade dynamic range, IEEE Transactions on Instrumentation and Measurement, 58, 2643-2652, (2009). Search in Google Scholar

Meeker J.D., Exposure to power-frequency magnetic fields and the risk of infertility and adverse pregnancy outcomes: update on the human evidence and recommendations for future study designs, J Toxicol Environ Health B 19, 29-45, (2016). Search in Google Scholar

Morega M., Baran I.M., Morega A.M., Evaluation of Environmental Low Frequency Magnetic Fields in Occupational Exposure, Proc. 8th Int. Conf. and Exposition on Electrical and Power Engineering EPE-2014, Iași, 522-527. Search in Google Scholar

Mujezinovic A., Turajlic E., Alihodzic A., Dautbasic N., Dedovic M.M., Novel method for magnetic flux density estimation in the vicinity of multi-circuit overhead transmission lines, IEEE Access 2022, 10, 18169-18181. Search in Google Scholar

Nica I., David V., Pavel I., Sălceanu A., Automatic Long Term Survey of Magnetic Fields in Residential Areas, Instrumentation and Measurements, Environ. Engng. a. Manag. J., 12, 15, 2631-2640 (2016). Search in Google Scholar

Pavel I., David V., Donose C., A Measurement System for the Automatic Survey of the Low Frequency Magnetic Field, 10th International Conference and Exposition on Electrical and Power Engineering (EPE), 2018, Iași, Romania, 18, 568-571. Search in Google Scholar

Pavel I., Petrescu C., David V., Lunca E., Estimation of the Spatial and Temporal Distribution of Magnetic Fields around Overhead Power Lines—A Case Study, Mathematics, 11, 2292, 1-15 (2023). Search in Google Scholar

Pop I.T., Munteanu C., Topa V., Racasan A., Merdan E., Human exposure to power frequency electric field inside very high voltage substations, Environmental Engineering and Management Journal, 10, 499-504 (2011). Search in Google Scholar

Sadafi H.A., Wood A.W., Bailey M., Wesnes K., The brain effects of occupational strength 50 Hz magnetic field, 2003 IEEE International Symposium on Electromagnetic Compatibility, 2003, May 2005, Istambul, Turkey, 3, 832-835. Search in Google Scholar

Turner M.C., Benke G., Bowman J.D., Figuerola J., Fleming S., Hours M., Kincl L., Krewski D., McLean D., Parent M.E., Richardson L., Sadetzki S., Schlaefer K., Schlehofer B., Schüz J., Siemiatycki J., Tongeren M.V., Cardis E., Occupational exposure to extremely low frequency magnetic fields and brain tumour risks in the INTEROCC study, Cancer Epidemiol Biomarkers Prev 23, 1863-1872 (2014). Search in Google Scholar

WHO, Extremely low frequency magnetic fields. Environmental Health Criteria 238, Geneva: World Health Organization, 239-254 (2007). Search in Google Scholar

Zaryabova V., Shalamanova T., Israel M., Pilot study of extremely low frequency magnetic fields emitted by transformers in dwellings, Social aspects, Electromagn Biol Med, 32, 209-217 (2013). Search in Google Scholar

*^** Directive 2013/35/EU of the European Parliament and of the Council, Off. J. Eur. Union 2013, 179, 12-18. Search in Google Scholar

*^** Guidelines for Limiting Exposure to Time-Varying Electric and Magnetic Fields (1 Hz to 100 kHz), International Commission on Non-ionizing Radiation Protection, Health Physics, 99, 818-836 (2010). Search in Google Scholar

*^** Hotărâre nr. 520/2016, Cerinţele minime de securitate şi sănătate referitoare la expunerea lucrătorilor la riscuri generale de câmpuri electromagnetice, Monitorul Oficial, https://www.snppc.ro/uploads/fisiere/articole/HG-520-2016.pdf Search in Google Scholar

*^** ICNIRP guidelines for limiting exposure to time-varying electric, magnetic and electromagnetic fields (up to 300 GHz), Health Physics, 74, 494-522 (1998). Search in Google Scholar

*^** IEEE Standards Coordinating Committee 39, IEEE Standard for Safety Levels with Respect to Human Exposure to Electric, Magnetic, and Electromagnetic Fields, 0 Hz to 300 GHz, IEEE Std C95.1-2019 (Revision of IEEE Std C95.1-2005/ Incorporates IEEE Std C95.1-2019/Cor 1-2019), 1-17. Search in Google Scholar