Your search keyword '"Yujun Guo"' showing total 12 results

1. Modeling of Stray Currents From Metro Intruding Into Power System Considering the Complex Geological Conditions in Modern Megacities

Author

Chunmao Li, Qing Du, Yujun Guo, Yijie Liu, Feng Yang, Lu Chen, Xueqin Zhang, Guizao Huang, Guoqiang Gao, and Guangning Wu

Subjects

Automotive Engineering, Energy Engineering and Power Technology, Transportation, Electrical and Electronic Engineering

Published

2023

2. Experimental study on dynamic response characteristics of isolated‐span transmission lines after ice‐shedding

Author

Guizao Huang, Bo Yan, Yujun Guo, Bo Zhang, and Guangning Wu

Subjects

Energy Engineering and Power Technology, Electrical and Electronic Engineering

Published

2022

3. Research on the arcing horn with active arc extinguishing function for HVDC grounding electrode line

Author

Yicen Liu, Chenguang Yang, Yujun Guo, Xueqin Zhang, Xiao Lei, Guoqiang Gao, and Guangning Wu

Subjects

Control and Systems Engineering, Energy Engineering and Power Technology, Electrical and Electronic Engineering

Published

2023

4. Systematic protective scheme for mega‐city power systems against stray currents caused by metro systems

Author

Yujun Guo, Qing Du, Yijie Liu, Feng Yang, Lu Chen, Xueqin Zhang, Song Xiao, Chunmao Li, and Guangning Wu

Subjects

Energy Engineering and Power Technology, Electrical and Electronic Engineering

Published

2023

5. Pollution morphology characteristics on a superhydrophobic surface and its pollution flashover voltage in DC electric field

Author

Guizao Huang, Liu Yijie, Yujun Guo, Xueqin Zhang, Zhang Guangquan, Bo Wang, Yicen Liu, Guangning Wu, and Deng Qin

Subjects

Surface (mathematics), Pollution, Materials science, Morphology (linguistics), Electric field, media_common.quotation_subject, Pollution flashover, Energy Engineering and Power Technology, Electrical and Electronic Engineering, Composite material, Voltage, media_common

Published

2021

6. Method for detecting the pollution degree of naturally contaminated insulator based on hyperspectral characteristics

Author

Chengfeng Yin, Zhang Xiao, Guangning Wu, Xueqin Zhang, Chaoqun Shi, and Yujun Guo

Subjects

QC501-721, Pollution, Materials science, media_common.quotation_subject, Energy Engineering and Power Technology, Hyperspectral imaging, Insulator (electricity), Contamination, TK1-9971, Degree (temperature), Electricity, Electrical engineering. Electronics. Nuclear engineering, Electrical and Electronic Engineering, Remote sensing, media_common

Abstract

Insulator pollution degree detection is of great significance for preventing a flashover. Equivalent salt deposit density, leakage current, and surface pollution layer conductivity are commonly used to describe insulator pollution degree; however, all these parameters have limitations in field application and real‐time monitoring. Non‐contact detection methods, such as infrared thermal imaging and ultraviolet imaging, only image insulators in a specific band, which makes the extracted features limited. Hyperspectral technology is the new comprehensive image data technology based on imaging spectroscopy that has the advantages of multiband high resolution. Therefore, a method based on hyperspectral image and spectral characteristics is proposed to fully characterize natural pollution information and accurately detect the pollution degree of insulators. The hyperspectral spectral line characteristics, image texture, and colour characteristic data of insulators were extracted and fused and then used to establish the pollution degree detection model on the basis of integrated learning classification algorithms. The results show that the model based on fusion data has an accuracy rate of 95.0%, which is more accurate than the model based on spectral line features only. Consequently, hyperspectral technology can realize the non‐contact detection of pollution degree and provide some guidance for cleaning the contamination of external insulation.

Published

2021

7. Study on the Discharge Characteristics along the Surface and Charge Movement Characteristics of Insulating Media in an Airflow Environment

Author

Guangquan Zhang, Xueqin Zhang, Bo Wang, Yujun Guo, Guoqiang Gao, and Guangning Wu

Subjects

Condensed Matter::Quantum Gases, Control and Optimization, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Condensed Matter::Strongly Correlated Electrons, airflow environment, discharge along the surface, insulation media, conduction mechanism, trap level, electric charge motion, Electrical and Electronic Engineering, Engineering (miscellaneous), Energy (miscellaneous)

Abstract

The gas–solid interface of high-voltage insulating equipment is a weaker part of insulating equipment insulation, and preventing the occurrence of discharge along the surface of insulating equipment is a critical problem for high-voltage insulation. This article investigates the discharge characteristics and charge movement characteristics of insulating media under an airflow environment. The surface discharge characteristics of the insulating medium in the airflow environment were obtained by using a high-velocity airflow test platform, and the surface discharge voltage characteristics, discharge path characteristics, and force conditions of the discharge process were analyzed. The surface charge motion characteristics of the insulating medium in the high-velocity airflow environment were also tested, and the distribution characteristics, dissipation characteristics and conduction mechanism of the surface charge of the insulating medium in the high-velocity airflow environment were revealed. The research results showed that: the discharge voltage along the insulating medium surface gradually increases with the increasing velocity of airflow; the discharge path along the surface of the insulating medium gradually shifts backward under the action of airflow; under the action of airflow, the charge on the insulating medium surface is blown away, thus reducing the charge concentration on the insulating medium surface; the trap level center of the insulating medium gradually decreases under the action of airflow, which provides the conditions for the charge blowing effect on the insulating medium surface. This investigation supplies the theory support for the protection of insulation equipment in an airflow environment and technical guidance for the insulation design of insulating equipment in an airflow environment to ensure the secure and steady running of insulating equipment in high-speed trains and high-voltage transmission lines.

Published

2022

8. Pollution accumulation characteristics of insulators under natural rainfall

Author

Zhigao Meng, Xingliang Jiang, Zidan Jiang, Yuyao Hu, and Yujun Guo

Subjects

010302 applied physics, Rainy weather, Hydrology, Pollution, Splash, Meteorology, 020209 energy, media_common.quotation_subject, Energy Engineering and Power Technology, Insulator (electricity), 02 engineering and technology, Contamination, 01 natural sciences, Control and Systems Engineering, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Environmental science, Insulator contamination, Electrical and Electronic Engineering, Salt deposit density, media_common

Abstract

Under natural environment, the washing effect of rainfall has great influence on the cleaning of outdoor insulators. To study the law of natural contamination on the insulator surface in the rainy weather. The natural contamination experimental study has been carried out for four 500 kV transmission lines in hundreds of sites and stations in Hunan Province for five years. The equivalent salt deposit density (ESDD) and non-soluble deposit density (NSDD) were measured monthly, and the meteorological data were statistically analysed. The results show that the residual ESDD and NSDD on the surface of insulators were affected by the rainfall intensity, duration and flushing angle. Meanwhile, based on the measured data of ESDD and NSDD, a cleaning model of insulators was established. The effects of splash on the bottom surface of insulators were studied by using the raindrop kinetic energy and Gaussian probability statistical distribution.

Published

2017

9. Additional salt deposit density of polluted insulators in salt fog

Author

Xingliang Jiang, Zhenyu Li, Zhigao Meng, Zidan Jiang, and Yujun Guo

Subjects

010302 applied physics, Materials science, 020209 energy, Energy Engineering and Power Technology, Insulator (electricity), 02 engineering and technology, Conductivity, Composite insulators, 01 natural sciences, Surface conductivity, Control and Systems Engineering, 0103 physical sciences, Pollution flashover, 0202 electrical engineering, electronic engineering, information engineering, Arc flash, Geotechnical engineering, Wetting, Electrical and Electronic Engineering, Composite material, Salt deposit density

Abstract

The surface pollution layer of polluted insulator absorbs fog water and gets damp in salt fog. Meanwhile, the salts in the salt fog deposit on insulator surface, which increases the surface conductivity and degrades the flashover performance of insulators. At present, the effects of fog water conductivity (γ 20) and equivalent salt deposit density (ESDD) are analysed separately, which does not reveal the essence of the flashover in salt fog. In this study, a plenty of experiments on porcelain, glass and composite insulators are carried out in salt fog conditions, and the 50% flashover voltage stress, leakage current and variation of ESDD during the wetting process are studied. The concept of additional salt deposit density (ASDD) is proposed to quantitatively analyse the additional ESDD caused by salt fog. The test results indicate that the ac flashover voltage stress decreases with the increase of both ESDD and fog-water conductivity. Both the ESDD and leakage current become larger in salt fog compared with those in clean fog. The ASDD can be applied to analyse the combined effect of ESDD and fog-water conductivity and be expressed as ASDD = k × γ 20 × ESDD. Then the flashover voltage stress is E = A × (ESDD + ASDD)−a . The values of k for the porcelain, glass and composite insulators are 0.179, 0.191 and 0.230, respectively. The flashover in salt fog environment is a special kind of pollution flashover in essence.

Published

2016

10. AC flashover characteristics of insulators under haze–fog environment

Author

Zhenyu Li, Yang Liu, Zhigao Meng, Xingliang Jiang, and Yujun Guo

Subjects

010302 applied physics, Pollution, Haze, Materials science, 020209 energy, media_common.quotation_subject, Environmental engineering, Energy Engineering and Power Technology, Insulator (electricity), 02 engineering and technology, Conductivity, 01 natural sciences, Flashover voltage, Control and Systems Engineering, 0103 physical sciences, Pollution flashover, 0202 electrical engineering, electronic engineering, information engineering, Arc flash, Particle size, Electrical and Electronic Engineering, Composite material, media_common

Abstract

The occurrence of large-scale haze–fog weather in some developing countries brings a new threat to the safe operation of outdoor insulation. In order to study the effect of the haze–fog on the flashover performance of insulators and the flashover mechanism, kieselguhr, calcium sulphate (CaSO­ 4) and ammonium sulphate ((NH4)2SO4) in different particle sizes were mixed with ultrasonic fog to simulate the haze–fog environment and quantitative ac flashover experiments on the standard suspension porcelain insulator were carried out. The test results indicate that the flashover voltage is related with the pollution degree, particle component, particle size and fog-water conductivity, and may decrease by more than 20% under haze–fog environment. The effect of salt aerosols on flashover voltage is determined by the solubility and larger than that of non-soluble mineral aerosols or organic carbon aerosols. The flashover voltage increases with the increase of the particle size, but decreases with the increase of fog-water conductivity. The flashover of insulator under haze–fog condition is a special kind of pollution flashover in essence.

Published

2016

11. Pollution agglomeration characteristics on insulator and its effect mechanism in DC electric field

Author

Kai Liu, Kang Yongqiang, Guangning Wu, Xueqin Zhang, Yujun Guo, Liu Yijie, and Chaoqun Shi

Subjects

Pollution, Materials science, Condensed matter physics, Economies of agglomeration, 020209 energy, media_common.quotation_subject, 020208 electrical & electronic engineering, Energy Engineering and Power Technology, Insulator (electricity), 02 engineering and technology, Electrostatics, Aerosol, Dipole, Electric power transmission, Electric field, 0202 electrical engineering, electronic engineering, information engineering, Condensed Matter::Strongly Correlated Electrons, Electrical and Electronic Engineering, Physics::Atmospheric and Oceanic Physics, media_common

Abstract

To obtain the pollution agglomeration characteristics of insulators and its effect mechanism of Ultra High-Voltage DC transmission lines under natural sedimentary condition, a natural pollution accumulation system was set up and used to analyze the micro-shape features of the surface insulators on different conditions. The experimental results show that the surface pollution is respectively distributed as chain and granular shapes on the DC charged insulator and electrically neutral insulator, which indicates that the pollution agglomeration characteristics are influenced by the DC electric field significantly. Meanwhile, the radius of the pollution particles on the DC charged insulator is larger than that on the uncharged insulator. Based on the thermodynamics and electrostatics theory, this paper proposed the model of electric dipole between aerosol groups to explain the characteristics of the pollution distribution on the surface of the DC charged insulator and revealed the mechanism of aerosol particles radius affected by DC electric field. The conclusions of this paper can provide an experimental and theoretical basis for the UHV DC external insulation pollution characteristics and insulator flashover.

Published

2020

12. Investigating the Effect of Rainfall Parameters on the Self-Cleaning of Polluted Suspension Insulators: Insight from Southern China

Author

Yujun Guo, Yongfu Li, Zidan Jiang, Zhijin Zhang, and Xingliang Jiang

Subjects

Wet season, Control and Optimization, Meteorology, non-soluble deposit density (NSDD), Energy Engineering and Power Technology, Insulator (electricity), insulator, 010501 environmental sciences, lcsh:Technology, 01 natural sciences, contamination, 0103 physical sciences, Dry season, Arc flash, medicine, Electrical and Electronic Engineering, Engineering (miscellaneous), 0105 earth and related environmental sciences, 010302 applied physics, Hydrology, functional relationship, lcsh:T, Renewable Energy, Sustainability and the Environment, rainfall intensity, Mist, Seasonality, Contamination, equivalent salt deposit density (ESDD), medicine.disease, Environmental science, Dew, Energy (miscellaneous)

Abstract

The cleaning effect of heavy rain (the rainfall reaches 5 mm every day) on surface contamination of insulators is more effective than dew, fog, mist, and other light rain conditions which can initiate leakage currents and increase the likelihood of flashover. It is well understood that heavy rain can wash away contamination from the surface of high voltage (HV) insulators and thereby reduce the risk of pollution flashover. This study examines the cleaning effect of natural wetting conditions on HV insulators on four 500 kV transmission lines in Hunan Province, China. Historical meteorological data, monthly equivalent salt deposit density (ESDD) and non-soluble deposit density (NSDD) measurements taken over a period of five years were analyzed to investigate the relationship between rainfall intensity and insulator cleaning. The measured data show that the ESDD/NSDD changes with the seasonal variation, which accumulates in dry season (January–April, about 117–122 days) and is washed off in the wet season (June–October, about 118–127 days). According to the measured data, the ESDD and NSDD on the surface of insulators were affected by the rainfall intensity (in the dry season it is about 1 mm/day and in the wet season it is about 5 mm/day). Based on a comparison of the four study sites, we propose a mathematical model to show the functional relationship between rainfall intensity and insulator self-cleaning capability. The mathematical model’s coefficient of determination (R2) is greater than 0.9 and the effective rate of self-cleaning capability reaches 80%.

Published

2017