The Investigating and Simulating the Corona Phenomenon in The Power Transmission Lines of Power Networks Using the Finite Element Method
Subject Areas :
Majlesi Journal of Telecommunication Devices
noushin dadashzadeh
1
,
Elnaz poorreza
2
,
Vahide Mohadesi
3
1 - Department of Electrical Engineering, Aras Branch, Islamic Azad University, Jolfa, Iran
2 - Department of Electrical Engineering, Sahand University of Technology, Tabriz, Iran
3 - Department of Electrical Engineering, Sarab Branch, Islamic Azad University, Sarab, Iran
Received: 2022-11-19
Accepted : 2023-01-14
Published : 2023-03-01
Keywords:
Corona DC discharge,
power systems,
Ionisation,
Plasma,
Finite Element Method,
Abstract :
In this article, the simulation of the physical phenomenon of coaxial corona discharge in air, in DC mode using the finite element method is discussed. Basically, to optimize the production process of ionized gas and any other physical phenomenon, we model and simulate the phenomenon. To simulate this phenomenon, from two cylindrical electrodes, one inside (cathode) and the other outside (anode), the radius of the inner electrode is 100 microns and the distance between the electrodes is 10 cm. A constant voltage of 50 kV is applied to the inner electrode. The outer electrode is considered the ground. Our emphasis is on the formation of charged particles and their behavior in the resulting electric field. In order to avoid the complexity of the problem and save the simulation time, we model in a one-dimensional way and in the results extract the above phenomenon in a two-dimensional way. The gas temperature is 640 K and the air density is considered constant.
References:
[1] Cui, C. Zhuang, and R. Zeng, “Electric field measurements under DC corona discharges in ambient air by electric field induced second harmonic generation,” Applied Physics Letters, vol. 115, no. 24, p. 244101, 2019.
[2] G. Ferreira et al., “Computational and experimental study of time-averaged characteristics of positive and negative DC corona discharges in point-plane gaps in atmospheric air,” IEEE Transactions on Plasma Science, vol. 48, no. 12, pp. 4080-4088, 2020.
[3] Lühring, D. Wienold, and F. Jenau, “Investigation on the pulse shape of DC corona discharges in air under varying test voltage level,” in 2018 IEEE 2nd International Conference on Dielectrics (ICD), 2018: IEEE, pp. 1-6.
[4] Friebe, D. Wienold, and F. Jenau, “Optimized Numerical Modeling and Validation of negative DC Corona Discharges by using Pulse Shape Parameters,” in 2020 55th International Universities Power Engineering Conference (UPEC), 2020: IEEE, pp. 1-5.
[5] Ferreira, P. Almeida, M. Benilov, and G. Naidis, “Comment on “Electric field measurements under DC corona discharges in ambient air by electric field induced second harmonic generation,” [Appl. Phys. Lett. 115, 244101 (2019)]," Applied Physics Letters, vol. 117, no. 2, p. 026101, 2020.
[6] T. Nguyen et al., “Removal of ethyl acetate in air by using different types of corona discharges generated in a honeycomb monolith structure coated with Pd/γ-alumina,” Journal of Hazardous Materials, vol. 416, p. 126162, 2021.
[7] Liu, R. Liao, X. Zhao, and Y. Lin “The effect of air pressure on the surface electric field intensity characteristics under negative DC corona discharge in a corona cage,” International Journal of Electrical Power & Energy Systems, vol. 113, pp. 244-250, 2019.
[8] Pekárek, “DC corona discharge ozone production enhanced by magnetic field,” The European Physical Journal D, vol. 56, no. 1, pp. 91-98, 2010.
[9] -R. Riba, A. Morosini, and F. Capelli, “Comparative study of ac and positive and negative dc visual corona for sphere-plane gaps in atmospheric air,” Energies, vol. .11 no. 10, p. 2671, 2018.