Experimental studies have been carried out on High-Voltage Overhead Power Lines (HVOPL) in order to determine the energy characteristics of the induced energy in the ground wire cable, taking into account the peculiarities of its grounding. The experimentally obtained results have been used in the development of simulation models of the HVOPL-500 sections located between the anchor supports. Simulation models of the anchor span with different numbers of supports have been built. As a result of simulation experiments, the dependences of power consumption as a function of the load resistance and voltage across the ground wire have been obtained. Based on the obtained dependences, recommendations have been developed for various options of power supply for the telemetry system components placed on the HVOPL-500 kV supports. In the course of simulation experiments, the maximum values of power and the corresponding voltage values on the ground wire as a function of the load resistance value have been determined. Technical solutions and recommendations have been proposed for providing power supply to the components of diagnostic systems and monitoring the state of structural elements of the supports.
Copyright © 2021 Praise Worthy Prize - All rights reserved.

F. Kiessling, P. Nefzger, J.F. Nolasco, U. Kaintzyk, Overhead Power Lines, Planning, Design, Construction (Berlin: Springer-Verlag Berlin Heidelberg, 2003, 1-8).
https://doi.org/10.1007/978-3-642-97879-1_1

https://www.energycharter.org/fileadmin/DocumentsMedia/Events/20070426-Bishkek_Kazakhstan_Katyshev_en.pdf

R. Sacaan, T. Lagos, A. Navarro-Espinosa, H. Rudnick, F. Ordonez, and R. Moreno, Improving Power System Reliability through Optimization via Simulation, 2017.
https://doi.org/10.1109/PTC.2017.7981193

V. E. Vorotnitskiy, Reducing energy losses - the most important way of energy saving in electrical networks, Energy saving, No. 4, April 2014, pp. 52-58.
https://www.abok.ru/for_spec/articles.php?nid=5858

B. Adjei-Frimpong, K. Akom, and J.F. Rushman, How to Improve Power System Reliability in Ghana, 2016.

M. I. Toshkhodjayeva, Elevation of reliability of electricity supply system as a factor of sustainable provision of national economy with electric power, Bulletin of TSUPBP, No. 3, 2015. URL:
https://cyberleninka.ru/article/n/povyshenie-nadezhnosti-sistemy-elektrosnabzheniya-kak-faktor-ustoychivogo-obespecheniya-narodnogo-hozyaystva-elektroenergiey-na

Y. Yang, G. Xie, X. Xu, and Y. Jiang, A Monitoring System Design in Transmission Lines based on Wireless Sensor Networks, Energy Procedia, vol. 12, 2011, pp. 192-199, ISSN 1876-6102.
https://doi.org/10.1016/j.egypro.2011.10.027

Dr. A. Peabody, Evolution of Real-time Monitoring and its Future Benefits, IWAIS XIII, Andermatt, September 8 to 11, 2009.
https://www.compusult.com/html/IWAIS_Proceedings/IWAIS_2009/Session_4_cost_727_wg2/session_4_peabody.pdf

A. Samarin, and V. Massalov, Up-to-date technologies of monitoring overhead power transmission lines, Сontrol Engineering, No. 3, June 2013, pp. 89-94.
https://controleng.ru/wp-content/uploads/ce_45_p88_sovremennye_tekhnologii_monitoringa_vozdushnykh_elektrosetey_lep.pdf

R. K. Borisov, S. S. Zhulikov, P. S. Glazunov, et al., A Hardware and Software Complex for Remote Monitoring of a High-Voltage Line Arrester under Operating Voltage, Russ. Electr. Engin. 90, pp.130-134.
https://doi.org/10.3103/S1068371219020019

К. Morozovska, and Р. Hilber, Study of the Monitoring Systems for Dynamic Line Rating, Energy Procedia, vol. 105, 2017, pp. 2557-2562, ISSN 1876-6102.
https://doi.org/10.1016/j.egypro.2017.03.735

A.H. Khawaja, Q. Huang, and Z.H. Khan, Monitoring of Overhead Transmission Lines: A Review from the Perspective of Contactless Technologies, Sens Imaging 18, 24 (2017).
https://doi.org/10.1007/s11220-017-0172-9

D. Douglass et al. Real-Time Overhead Transmission-Line Monitoring for Dynamic Rating, IEEE Transactions on Power Delivery, Vol. 31, No. 3, pp. 921-927, June 2016.
https://doi.org/10.1109/TPWRD.2014.2383915

S. Uski-Joutsenvuo, R. Pasonen, Maximizing power line transmission capability by employing dynamic line ratings - technical survey and applicability in Finland (VTT Technical Research Centre of Finland, Finland, Feb. 2013).
http://sgemfinalreport.fi/files/D5.1.55%20-%20Dynamic%20line%20rating.pdf

V. V. Kaverin, V. G. Khomchenko, and Sh. Ye. Yezhebayeva, Review and analysis of existing power supplies for monitoring systems located on the supports of overhead power lines, Presented at Proceedings (Saginov's Readings), No. 12, June 2020, Karaganda, Kazakhstan, pp. 743-745.
https://www.kstu.kz/wp-content/uploads/2020/08/Sbornik-chast-1-2020.pdf

N. Kaliaskarov, V. Ivel, Y. Gerasimova, V. Yugay, S. Moldakhmetov, Development of a distributed wireless Wi-Fi system for monitoring the technical condition of remote objects, Eastern-European Journal of Enterprise Technologies, 5(9 (107), 36-48, 2020.
https://doi.org/10.15587/1729-4061.2020.212301

I. Breido, V. Kaverin, and V. Ivanov, Telemetric Monitoring Insulation Condition of High Voltage Overhead Power Lines, Presented at Proceedings of the 29th DAAAM International Symposium, 2018, pp. 0319-0328.
https://doi.org/10.2507/29th.daaam.proceedings.046

I. Breydo, V. Kaverin, V. Ivanov, S. Voytkevich, and I. Levin, Distributed system of protection and diagnostics of support structural elements of high-voltage power lines, EAI Endorsed Transactions on Energy Web, vol. 4, July 2017.
https://doi.org/10.4108/eai.3-8-2017.152983

J. Lin, B. Zhu, P. Zeng, W. Liang, H. Yu, and Y. Xiao. Monitoring power transmission lines using a wireless sensor network, Wireless Communications and Mobile Computing, 15, 2014.
https://doi.org/10.1002/wcm.2458

https://microtronics.com/en/references/overhead-power-line-monitoring/

V. V. Bessel, V. G. Kucherov, and R. D. Mingaleyeva, Studying solar photovoltaic cells (Publishing Center of the Russian State University of Oil and Gas named after I.M. Gubkin, 2016).
http://www.gubkin.ru/faculty/pipeline_network_design/chairs_and_departments/thermodynamics_and_thermal_engine/files/Bessel_photovoltaiccells.pdf

T. Bajenescu, Some Reliability Aspects of Photovoltaic Modules, 2020.
https://doi.org/10.5772/intechopen.88641

A. I. Otto, Autonomous power plants with extreme power regulation of photovoltaic solar energy converters, candidate of technical sciences' dissertation, Elect. Comp. and syst., Tomsk St. Univ. of Contr. Syst. and Radioelectric., Tomsk, Russia, 2018.

T. Kita, Y. Harada, S. Asahi, Actual Calculation of Solar Cell Efficiencies, Energy Conversion Efficiency of Solar Cells, Green Energy and Technology, Springer, Singapore: 2012, pp. 81-137.
https://doi.org/10.1007/978-981-13-9089-0_6

R. L. Vasquez-Arnez, M. Masuda, J. A. Jardini, and E. J. V. Nicodem, Tap-off power from a transmission line shield wires to feed small loads, 2010 IEEE/PES Transmission and Distribution Conference and Exposition: Latin America, T and D-LA 2010, 116 - 121.
https://doi.org/10.1109/TDC-LA.2010.5762870

N. S. Savitsky, Induced electrostatic and electromagnetic voltages on lightning protection cables, presented at the Actual problems of energy: materials of the 72nd scientific and technical conference of students and graduate students, Minsk, Belarus, 2016, pp. 236-239.
https://rep.bntu.by/bitstream/handle/data/29082/Navedennye_ehlektrostaticheskie_i_ehlektromagnitnye_napryazheniya_na_grozozashchitnyh_trosah.pdf?sequence=1&isAllowed=y

H. Xiande, and Z. Hao, Simulation and analysis of induced voltage and induced current on overhead ground wire of Jindongnan-Nanyang-Jingmen 1000kV UHV AC transmission line, 4th International Conference on Electric Utility Deregulation and Restructuring and Power Technologies (DRPT), Weihai, China, 2011, pp. 622-625.
https://doi.org/10.1109/DRPT.2011.5993968

J. Furgał, Influence of Lightning Current Model on Simulations of Overvoltages in High Voltage Overhead Transmission Systems. Energies. Vol. 13, 2020, 296.
https://doi.org/10.3390/en13020296

V. Evgeni, and K. Evgeni, Characterization of Local Environmental Data and Lightning Caused Outages in the IECo Transmission Line Network, IEEE Transactions on Power Delivery, 31, 2015.
https://doi.org/10.1109/TPWRD.2015.2443032

Reza Shariatinasab & Javad Gholinezhad, The effect of grounding system modeling on lightning-related studies of transmission lines, J. appl. res. technol vol.15 no.6 Ciudad de México dic. 2017.
https://doi.org/10.1016/j.jart.2017.06.003

I. V. Breido, V. V. Kaverin, and S. V. Voitkevich, The system of cathodic protection of elements of supports of high-voltage power lines sections, RK Patent No. 29977, May 19, 2015.

I. V. Breido, V. V. Kaverin, G. A. Em, A. V. Sichkarenko, V. A. Ivanov, S. V. Voitkevich, Method of telemetric measurement of ice loads of high-voltage power lines and a system for its implementation, RK Patent No. 33249, Oct. 26, 2018.

S. Attaway, MATLAB: A Practical Introduction to Programming and Problem Solving, 4th ed. (Boston: Boston University, 2017, ISBN: 978-0-12-804525-1).

D. Mestriner, and M. Brignone, Corona Effect Influence on the Lightning Performance of Overhead Distribution Lines, Applied Sciences, 2020.
https://doi.org/10.3390/app10144902

R. Jordi-Roger, M. Andrea and C. Francesca, Comparative Study of AC and Positive and Negative DC Visual Corona for Sphere-Plane Gaps in Atmospheric Air. Energies, 2018.

M. Špes, and M. Márton, The impact of solar radiation for maximum current load of 400 kV power lines, POSTER, 2017.
http://poseidon2.feld.cvut.cz/conf/poster/poster2017/proceedings/Poster_2017/Section_PE/PE_022_Spes.pdf

Hasan, M., Mejeed, R., Hameed, H., Analysis of Diyala Power Network for the Distributed Feeders Between Iraq and Iran: 132 kV Baquba-Sarbilzahab, (2019) International Review of Electrical Engineering (IREE), 14 (5), pp. 359-366.
https://doi.org/10.15866/iree.v14i5.17122

Camacho, J., Chamorro, C., Caicedo, N., State of the Art of Teleoperated Energy Harvesting Systems for Small Hydropower Plants, (2019) International Review of Electrical Engineering (IREE), 14 (3), pp. 182-194.
https://doi.org/10.15866/iree.v14i3.16542