Optical Sensing System Based on Bidirectional Self-Correction Technology: An Online Detection Method for Carbon Disulfide and Sulfur Dioxide in Gas-Insulated Switchgear
Jie Gao, Yucun Zhang, Yucun Zhang, Rui Zhu, Mu Li, Fei Xie, Changyin Li, Bingqian Li, Yungang Zhang, Yungang Zhang
Abstract
Carbon disulfide (CS 2 ) and sulfur dioxide (SO 2 ) are typical indicative gases for the early warning and diagnosis of faults in gas-insulated switchgear. In this study, an optical sensing system is reported for online detection of CS 2 and SO 2 based on a bidirectional self-correction technology (BSCT). First, the differential absorption signals of CS 2 and SO 2 in the wavelength range of 195–230 nm are obtained using the UV differential optical absorption spectroscopy (UV-DOAS) technique. On this basis, a BSCT is proposed to decouple the spectral lines that exhibit significant overlap. This method primarily employs bidirectional difference spectroscopy to mutually correct the spectra of CS 2 and SO 2, combined with spectral reconstruction to extract the single-component absorption signals of CS 2 and SO 2 from the mixed gas spectra. Furthermore, the effectiveness of this novel decoupling technique is validated by comparing the decoupling results with the absorption spectra of single-component standard gases at corresponding concentrations. Finally, the quantitative relationships between the concentrations of target gases (CS 2, SO 2 ) and the optical parameters are modeled using the least-squares method. The experimental results show that the mean absolute percentage errors of CS 2 (19.00–3735.35 ppb) and SO 2 (0.19–38.77 ppm) are 0.543 and 0.521%, respectively. At an effective optical range of 50 cm, the system achieves the lowest detection limits of 0.5 ppb for CS 2 and 12 ppb for SO 2, representing the best results reported to date for the online detection of CS 2 and SO 2 in the ppb-ppm range.