Spectroscopy and Spectral Analysis, Volume. 41, Issue 2, 414(2021)
In-Situ Detection of SF6 Decomposition Products Based on Femtosecond Laser-Guided High-Voltage Discharge
The occurrence of discharge due to insulation defects in gas insulated switchgear (GIS) can cause decomposition of SF6. The low-fluoride sulfide species produced by the decomposition react with trace amounts of H2O and O2 in the equipment to produce corrosive substances, which affect the normal operation of the equipment. Thus, it is of great significance to study the decomposition mechanism for the safe operation of GIS. Some decomposition products are transformed in the process of sampling. Hence, it is necessary to realize the in-situ detection of SF6 decomposition products to study the mechanism of SF6 decomposition. Femtosecond laser-guided high-voltage discharge technology was proposed to achieve the precise control of the space and time of high-voltage discharge, and the in-situ measurement of SF6 decomposition products was achieved by using space-resolved spectrum generated by femto second laser-guided high-voltage discharge in our work. In this paper, firstly, the decomposition of SF6 is not caused by femtosecond laser. Secondly, the precise control of discharge space and time is achieved by using the plasma channel generated by femtosecond laser. Finally, it is found that the decomposition contains a large number of S and F ions and atoms that are directly or indirectly generated by high-energy electron collisions. The research proves that in-situ detection of SF6 decomposition products can be achieved based on femtosecond laser-guided high-voltage discharge, which provides a new research method for the study of SF6 decomposition mechanism under high-voltage discharge.
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Yun-gang ZHANG, Huang-tao LIU, Qiang GAO, Zhi-feng ZHU, Bo LI, Yong-da WANG. In-Situ Detection of SF6 Decomposition Products Based on Femtosecond Laser-Guided High-Voltage Discharge[J]. Spectroscopy and Spectral Analysis, 2021, 41(2): 414
Category: Research Articles
Received: Jan. 4, 2020
Accepted: Apr. 28, 2020
Published Online: Apr. 8, 2021
The Author Email: ZHANG Yun-gang (zhangyungang@hit.edu.cn)