Safety Management and Risk Control Strategy of High Voltage Power Line Installation and Construction
DOI: https://doi.org/10.62517/jsse.202408406
Author(s)
Shiwei Li1, Liuchuan Liu2, Qingjun Wang2,*
Affiliation(s)
1Chongqing Yongneng Industry Group Co., Ltd., Chongqing, China
2State Grid Chongqing Electric Power Company Yongchuan Power Supply Branch, Chongqing, China
*Corresponding Author.
Abstract
High voltage power line installation construction, safety management and risk control are the main premise to ensure the smooth progress of the project and personnel safety. In recent years, with the rapid development of the power system, the construction scale of high-voltage power lines is getting larger and larger, and the complexity and technical difficulty are gradually increasing. Therefore, how to carry out effective safety management and risk control has become an important link that cannot be ignored in the construction process. This paper focuses on the safety management and risk control strategy of high-voltage power line construction, with the purpose of formulating scientific and reasonable management strategy for power construction enterprises, so as to reduce the hidden dangers in construction and improve the quality and efficiency of the project. This paper first expounds the importance of construction safety management of high voltage power lines, discusses the industry safety standards, and analyzes the situation of safety management at home and abroad. Based on this, this paper makes an in-depth analysis of construction risks, uses appropriate methods to identify risks, and discusses common risk types and influencing factors. A series of safety management measures such as safety training for construction personnel, the use of advanced safety equipment and technology, and the establishment of strict safety supervision and assessment mechanisms are put forward to ensure the safety of personnel and equipment during construction. Finally, it puts forward specific risk control strategies, including risk control principles, specific implementation measures, preparation and implementation of risk emergency plans, in order to strengthen safety management during construction and minimize accidents. At the same time, it is emphasized that in the construction process of high-voltage power line construction, construction enterprises should adjust and improve their safety and risk management strategies according to the specific conditions of the project and construction environment. Through the detailed analysis and discussion of the above content, it is expected to provide some theoretical support and practical guidance for the construction of high-voltage power lines in the future.
Keywords
High Voltage Power Line; Safety Management; Risk Control; Construction Risk; Safety Measures
References
[1] Hsu S H, Tzu F M, Chang W H, et al. Assessing high-voltage shore connection safety: an in-depth study of grounding practices in shore power systems. Energies, 2024, 17 (6): 1373.
[2] Reddy S A, Kumari M S. A review of switching overvoltage modeling in UHV AC transmission lines. Electric Power Systems Research, 2024, 236: 110902.
[3] Jianhu Song, Jingpei Zhang, Xian Du, et al. Construction and Implementation of “Model Room for Ultra High Voltage Important Transmission Channels” Based on Digital Control// 2024 7th International Conference on Power and Energy Applications (ICPEA). IEEE, 2024: 1-6.
[4] Boukabou I, Kaabouch N. Electric and magnetic fields analysis of the safety distance for UAV inspection around extra-high voltage transmission lines. Drones, 2024, 8 (2): 47.
[5] Thabet A, Fouad M. Experimental and simulation analysis for insulation deterioration and partial discharge currents in nanocomposites of power cables. International Journal of Electrical & Computer Engineering (2088-8708), 2024, 14 (2).
[6] Dogan S, Kilicoglu C, Akinci H, et al. Comprehensive risk assessment for identifying suitable residential zones in Manavgat, Mediterranean Region. Evaluation and program planning, 2024, 106: 102465.
[7] Arora R, Mosch W. High voltage and electrical insulation engineering. John Wiley & Sons, 2022.
[8] Ferraz H, Gonçalves R S, Moura B B, et al. Automated classification of electrical network high-voltage tower insulator cleanliness using deep neural networks. International Journal of Intelligent Robotics and Applications, 2024: 1-15.
[9] Meng X, Tian L, Li C, et al. Copula-based wind-induced failure prediction of overhead transmission line considering multiple temperature factors. Reliability Engineering & System Safety, 2024, 247: 110138.
[10] Li X, Yang W, Liao Y, et al. Short-term risk-management for hydro-wind-solar hybrid energy system considering hydropower part-load operating characteristics. Applied Energy, 2024, 360: 122818.
[11] Nassereddine M. Transmission line earthing system; Advanced design diagram for safety compliance. Electric Power Systems Research, 2024, 233: 110489.
[12] Yang L, Fan J, Liu Y, et al. A review on state-of-the-art power line inspection techniques. IEEE Transactions on Instrumentation and Measurement, 2020, 69 (12): 9350-9365.
[13] Boukabou I, Kaabouch N. Electric and magnetic fields analysis of the safety distance for UAV inspection around extra-high voltage transmission lines. Drones, 2024, 8 (2): 47.
[14] Nyangon J. Climate-proofing critical energy infrastructure: Smart grids, artificial intelligence, and machine learning for power system resilience against extreme weather events. Journal of Infrastructure Systems, 2024, 30 (1): 03124001.
[15] Sun C, Min J. Dynamic trends and regional differences of economic effects of ultra-high-voltage transmission projects. Energy Economics, 2024, 138: 107871.
[16] Dikshit S, Dobson I, Alipour A. Cascading structural failures of towers in an electric power transmission line due to straight line winds. Reliability Engineering & System Safety, 2024, 250: 110304.
[17] Mircea P M. Electrical Safety in LV Energy Installations// Energy Transition Holistic Impact Challenge (ETHIC): A New Environmental and Climatic Era. Cham: Springer Nature Switzerland, 2024: 401-440.
