Breakdown process on rod–rod air gap under oscillating lightning impulse voltage

The puncture of glass fibre reinforced polymer (GFRP) laminate is a primary damage pattern of wind turbine blades due to lightning strikes. A numerical simulation model of positive streamer propagation in a needle-to-plate air gap with a GFRP laminate is established to investigate the breakdown mechanism of GFRP laminate. The model not only considers the dynamics of charged particles in the air and the composite laminate, but also the current continuity at gas-solid interfaces. The simulated streamer discharge pattern and the surface streamer length are in good agreement with the observation results. The distributions and evolutions of the electron number density, electric field, and surface charge densities during streamer propagation are obtained. It is found that the enhancement of the electric field on the GFRP laminate is caused by the rapid deposition of positive and negative space charges on the GFRP laminate after a secondary streamer incepts on the lower surface of the GFRP laminate. The effects of the applied voltage, relative permittivity, and thickness of the GFRP laminate on the electric field on the GFRP laminate are investigated. The obtained results could assist in further understanding of the mechanism of GFRP wind blade breakdown due to lightning strikes.This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

Section: Thickness Of Gfrpmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Simulation of positive streamer propagation in an air gap with a GFRP composite barrier

Xia

Luo

et al. 2021

“…The following breakdown phase is evitable when the streamer corona finally reaches the grounded plane [30]. The thin channel with high electrical conductivity bridges the high voltage (HV) electrode and the grounded plane.…”

Section: Introductionmentioning

confidence: 99%

“…Discharge processes with light-emitting have been extensively observed and studied by using optical imaging techniques, for example, streak camera [12,36], high-speed video camera [18,[37][38][39], or intensified charge-coupled device (ICCD) camera [30,40]. However, limited studies exist on lightless phases like dark periods or insulation recovery phases during which the thermodynamics process is predominant instead of the ionization process.…”

Section: Introductionmentioning

confidence: 99%

Schlieren techniques for observations of long positive sparks: Review and application

Wang

Zhao

et al. 2022

Understanding the mechanism of positive leader discharge is important in lightning protection engineering and the external insulation design in high voltage power transmission systems. During the propagation of a positive leader, some processes without light-emitting, for example, the insulation recovery process after the breakdown, cannot be observed by optical photography techniques. With the combination of the digital high-speed imaging system, the conventional Schlieren techniques offer new vistas in the long air gap discharge observation. The important features of high spatial resolution, high sensitivity, and easy arrangement make Schlieren techniques powerful and effective tools for characterising the discharge processes without light-emitting. This work presents a brief review of current Schlieren techniques and discusses the design of the Schlieren optics system for long spark observations. Several interesting phenomena discovered at different phases of long sparks with high-speed Schlieren techniques are also presented.

“…Streamer discharge is an important building block of gas discharges. As a natural phenomenon, it is the precursor of sparks [1,2] and lightning leaders in lower altitude [3][4][5][6][7] and can also be observed and captured directly, for example, the sprites in high altitude [8,9]. As a product of streamer discharges, the non-thermal atmospheric plasma paves the way to a large number of chemical reactions in applications such as the pollution control [10], solubilisation of carbon nano-material [11,12] and disinfection [13,14].…”

Section: Introductionmentioning

confidence: 99%

Adaptive strategies to fast multipole method in photoionisation calculations for streamer discharges

Lin

Zhuang

2022

Recently, a new framework to compute the photoionisation rate in streamer discharges accurately and efficiently using the integral model and the fast multipole method (FMM) was presented. This paper further improves the efficiency of this framework with adaptive strategies. The adaptive strategies are based on the magnitude of radiation and the electric field during the streamer propagation, and are applied to the selection of the source and target points. The accuracy and efficiency of this adaptive FMM are studied quantitatively for different domain sizes, pressures and adaptive criteria, in comparison with some existing efficient approaches to compute the photoionisation. It is shown that appropriate adaptive strategies reduce the calculation time of the FMM greatly, and maintain the high accuracy that the numerical error is still much smaller than other methods based on partial differential equations. The performance of the proposed adaptive method is also studied for a three-dimensional positive streamer interacting problem with a plasma cloud, which shows that the FMM with proper adaptive strategies is even faster than the partial differential equation based methods with efficient boundary conditions for the ionisation calculation.