Experimental and numerical analysis of damage characteristics to opgw strands under first lightning strike and continuous current

•The lightning damage modes of OPGWs due to different damage mechanisms were analyzed.•Damage parameters were defined to quantitatively evaluate lightning damage of OPGWs.•Lightning damage degree and distribution are affected by the electrode material.•Melting damage volume increased with action int...

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Veröffentlicht in:Electric power systems research 2020-10, Vol.187, p.106515, Article 106515
Hauptverfasser: Sun, Jinru, Yao, Xueling, Huang, Yang, Jiao, Zijia, Chen, Jingliang
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container_title Electric power systems research
container_volume 187
creator Sun, Jinru
Yao, Xueling
Huang, Yang
Jiao, Zijia
Chen, Jingliang
description •The lightning damage modes of OPGWs due to different damage mechanisms were analyzed.•Damage parameters were defined to quantitatively evaluate lightning damage of OPGWs.•Lightning damage degree and distribution are affected by the electrode material.•Melting damage volume increased with action integral according to a power function.•Lightning damage of OPGWs increases as dD decreases and FL increases. Optical fiber ground wires (OPGWs) are used to protect power transmission lines from lightning strikes. A lightning test system with a tension device was established to study the properties and influence factors of lightning damage for OPGWs under multiple consecutive lightning strikes composed of current impulse and continuous current. The lightning damage can be divided into arc sweeping damage, melting damage and ablation damage. The lightning energy injected through a W-Cu electrode was the most concentrated, leading to the most serious ablation damage and the smallest sweeping damage area. As the action integral and external tensile force increased, the lightning damage became more severe. The broken strands and ablation damage volume decreased as the discharge gap increased from 20 to 40 mm. In addition, a 3D finite element simulation of lightning melting damage was conducted considering the lightning test conditions. When 1850 K, which is close to the melting point of steel, was selected as the criterion temperature for melting damage, the deviations between the simulation and experimental results were less than 10%. [Display omitted]
doi_str_mv 10.1016/j.epsr.2020.106515
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Optical fiber ground wires (OPGWs) are used to protect power transmission lines from lightning strikes. A lightning test system with a tension device was established to study the properties and influence factors of lightning damage for OPGWs under multiple consecutive lightning strikes composed of current impulse and continuous current. The lightning damage can be divided into arc sweeping damage, melting damage and ablation damage. The lightning energy injected through a W-Cu electrode was the most concentrated, leading to the most serious ablation damage and the smallest sweeping damage area. As the action integral and external tensile force increased, the lightning damage became more severe. The broken strands and ablation damage volume decreased as the discharge gap increased from 20 to 40 mm. In addition, a 3D finite element simulation of lightning melting damage was conducted considering the lightning test conditions. When 1850 K, which is close to the melting point of steel, was selected as the criterion temperature for melting damage, the deviations between the simulation and experimental results were less than 10%. 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Optical fiber ground wires (OPGWs) are used to protect power transmission lines from lightning strikes. A lightning test system with a tension device was established to study the properties and influence factors of lightning damage for OPGWs under multiple consecutive lightning strikes composed of current impulse and continuous current. The lightning damage can be divided into arc sweeping damage, melting damage and ablation damage. The lightning energy injected through a W-Cu electrode was the most concentrated, leading to the most serious ablation damage and the smallest sweeping damage area. As the action integral and external tensile force increased, the lightning damage became more severe. The broken strands and ablation damage volume decreased as the discharge gap increased from 20 to 40 mm. In addition, a 3D finite element simulation of lightning melting damage was conducted considering the lightning test conditions. When 1850 K, which is close to the melting point of steel, was selected as the criterion temperature for melting damage, the deviations between the simulation and experimental results were less than 10%. 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Optical fiber ground wires (OPGWs) are used to protect power transmission lines from lightning strikes. A lightning test system with a tension device was established to study the properties and influence factors of lightning damage for OPGWs under multiple consecutive lightning strikes composed of current impulse and continuous current. The lightning damage can be divided into arc sweeping damage, melting damage and ablation damage. The lightning energy injected through a W-Cu electrode was the most concentrated, leading to the most serious ablation damage and the smallest sweeping damage area. As the action integral and external tensile force increased, the lightning damage became more severe. The broken strands and ablation damage volume decreased as the discharge gap increased from 20 to 40 mm. In addition, a 3D finite element simulation of lightning melting damage was conducted considering the lightning test conditions. 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subjects Ablation
Continuous fibers
Current impulses
Damage
Electric arc melting
Electric power lines
Electricity distribution
Fiber optics
Finite element analysis
Finite element method
Influencing factors, finite element simulation
Lightning
Lightning damage
Lightning strikes
Mathematical analysis
Melting points
Multiple lightning strikes
Numerical analysis
Optical fiber ground wires
Optical fibers
Power lines
Strands
Sweeping
Transmission lines
title Experimental and numerical analysis of damage characteristics to opgw strands under first lightning strike and continuous current
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