Highly sensitive fiber-enhanced Raman spectroscopy for simultaneous detection of SF6 decomposition

Zhou Feng, Wan Fu, Jianxin Wang, Hu Jin, Hangyin Mao, Wang Pinyi, Chengzhi Zhu, Weigen Chen
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Abstract

As the insulating medium, sulfur hexafluoride (SF6) is widely applied in gas insulation equipment. Over longterm operation, the solid insulation of the equipment is damaged by PD, causing it to react with SF6 to generate COS and CF4 which are critical SF6decomposition products inside the equipment. The detection of these two SF6 decomposition products can help in assessment of the type and severity of insulation defects. Compared to the absorption spectroscopy and photoacoustic spectroscopy, FERS can using a single wavelength laser to simultaneously achieve the high sensitivity detection of mixture gases. In this paper, a highly sensitive SF6 decomposition based on fiber-enhanced Raman spectroscopy is built up. The Raman spectroscopy of COS and CF4 was acquired. The characteristic peak of COS at 859 cm−1 and that of CF4 at 909 cm−1 were observed respectively. We study the relationship between laser power, pressure of fiber core and Raman scattering intensity, experimentally. The Raman scattering intensity is linear related to laser power and pressure. The response time of FERS which includes the filling time and evacuating time. was also examined. The filling time of the fiber is defined as the point when the intensity of the Raman peak does not change. FERS is promising to achieve the online monitoring technique to detect the SF6 decomposition components with highly selective and sensitive.
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同时检测SF6分解的高灵敏度纤维增强拉曼光谱
六氟化硫(SF6)作为绝缘介质广泛应用于气体绝缘设备中。在长期运行中,PD会破坏设备的固体绝缘,使其与SF6反应生成COS和CF4,这是设备内部SF6分解的关键产物。检测这两种SF6分解产物可以帮助评估绝缘缺陷的类型和严重程度。与吸收光谱法和光声光谱法相比,FERS可以利用单波长激光同时实现对混合气体的高灵敏度检测。本文建立了一种基于光纤增强拉曼光谱的高灵敏度SF6分解方法。获得了COS和CF4的拉曼光谱。在859 cm−1处观察到COS的特征峰,在909 cm−1处观察到CF4的特征峰。实验研究了激光功率、光纤芯压力与拉曼散射强度之间的关系。拉曼散射强度与激光功率和压力成线性关系。FERS的响应时间,包括填充时间和疏散时间。也进行了检查。纤维的填充时间定义为拉曼峰强度不变的时间点。FERS有望实现高选择性、高灵敏度的SF6分解组分在线监测技术。
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