Simulation of corona space charge generated from the ±800kV UHVDC overhead transmission line in a thunderstorm

Chen, Shanshan; He, Hengxin; Zou, Yanhui; He, Junjia; Chen, Weijiang

doi:10.1109/ichve.2016.7800706

Cited by 4 publications

(1 citation statement)

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“…Simulations of corona discharge under different wind conditions and on multiple tips were achieved. Chen (2018) established a model of corona discharge for 2D high-voltage transmission lines and discussed the spatiotemporal evolution of corona ions around the line of the E-field during a thunderstorm. However, the limitations to the 2D model, such as the inability to obtain the characteristics of the spatiotemporal evolution of corona charges in 3D space and the underestimation of the E-field and the effects of its distortion (lack of a horizontal component), highlight the need to carry out high-resolution 3D simulations of this phenomenon.…”

Section: Introductionmentioning

confidence: 99%

3D Corona Discharge Model and Its Use in the Presence of Wind During a Thunderstorm

Guo

Gao

et al. 2022

Front. Environ. Sci.

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In this study, the authors developed a three-dimensional (3D) numerical model for the diffusion of positive corona charges based on a 2D model with a uniform grid to explore the characteristics of corona discharge at a building tip during a thunderstorm in the presence of wind. The variable-grid meshing method is used to solve the problems of implementing a large simulation domain for thunder clouds (kilometer-scale) and the minute calculations of corona discharge at the tip (centimeter scale) in the 3D numerical simulation. The proposed model has advantages in terms of the acquisition of the parameters of corona charges and the spatial distribution of the electric field (E-field) in the environment. We used positive corona discharge at the tip of a building under a negative thunderstorm, along with three wind fields (horizontal wind, updraft, and downdraft with wind speeds of 10 m/s) as an example. The presence of the wind increased the density of corona charges at the tip, where the horizontal wind was the most beneficial for its occurrence. Moreover, the characteristics of distortion of the electric field around the tip were significantly different, owing to the different directions of the wind. Downdraft led to the maximum enhancement in the E-field above the tip, and updraft prompted the minimum increase in it, by only 1.19 times. However, the opposite results were obtained for the enhancement in the spatial range of the charges: The updraft led to the greatest increase in it, and the downdraft caused the smallest. Corona charges had an apparent shielding effect on the E-field below the tip and can even change the polarity of the E-field in a small area close to it. The strongest shielding effect on the ground E-field occurred in the case of the downdraft, which decreased the E-field to 0.36 times compared with that without the corona charges. On the contrary, corona discharge had the weakest shielding ability on the ground when it met the updraft. The horizontal wind had the largest range of shielding on the ground, of up to 14,699.36 m2, while the updraft had the lowest, at only 6,170.91 m2.

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Section: Introductionmentioning

confidence: 99%