METHODS FOR PREVENTING ICE PROCESSES OF HIGH-VOLTAGE AIR LINES IN AREAS WITH A SEVERE CLIMATE CHANGE
DOI:
https://doi.org/10.47390/ts-v3i5y2025N14Keywords:
high-voltage overhead line, freezing process, mechanical device, vibration devices, SCADA system, modeling in the MATLAB environment, power outages. Keywords: High-voltage overhead line, ice formation process, mechanical device, vibration devices, SCADA system, MATLAB modeling, power outagesAbstract
This article discusses the freezing processes that occur in winter on the 220 kV Zarafshan-Muruntau high-voltage overhead lines and methods for eliminating them. The article describes the dangerous consequences of ice accumulation on wires, weighting of wires and the occurrence of power outages. Based on experimental studies, mechanical means of protection against freezing - vibration, roller and automatic devices - were analyzed. The coefficient of ice mass reduction as a result of mechanical action and methods for determining it using modeling are indicated. The possibilities of real-time ice mass estimation and control using MATLAB and SCADA systems were also analyzed. The results confirm the effectiveness of using mechanical devices in practice
References
1. Голубков Г.А. Линии электропередачи: теория, расчет, проектирование. — Москва: Энергоатомиздат, 2020.
2. Сизов В.А., Колчинский А.П. Надежность воздушных линий электропередачи в условиях гололёда и обледенения. — Санкт-Петербург: Энергия, 2018.
3. Поляков С.В. Противообледенительные устройства и методы защиты ЛЭП. — Москва: Энергоиздат, 2019.
4. ISO 12494:2017 – Atmospheric Icing of Structures. — International Organization for Standardization, 2017.
5. Sharma, R. K., & Singh, M. (2021). Smart Monitoring and Ice Prevention in Power Transmission Lines Using IoT and AI Techniques. — International Journal of Electrical Power & Energy Systems, 134, 107320.
6. Горелов А.А. Физика атмосферных осадков и гололедообразования. — Санкт-Петербург: Гидрометеоиздат, 2017.
7. Жуков Ю.П., Климов А.Н. Методы и средства защиты воздушных линий электропередачи от гололёда и ветровых нагрузок. — Москва: Энергия, 2020.
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