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| Simulation Analysis and Experiment Verification of Insulating Material-Based Photoacoustic Cell |
| CHEN Tu-nan1, 2, LI Kang1, QIU Zong-jia1, HAN Dong1, 2, ZHANG Guo-qiang1, 2* |
1. Institute of Electrical Engineering, Chinese Academy of Sciences,Beijing 100190,China
2. University of Chinese Academy of Sciences,Beijing 100049,China
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Abstract High voltage bushing is one of the core components in a power system. Therefore, it is with significant meaning to monitor the insulation status. However, current commercial equipment for online monitoring is not suitable for bushing with special locations and small sizes. As a result, developing a detection system for bushing specifically is necessary. In-situ detection is one of the theoretically feasible ways for bushing monitoring. Compared with metal material, photoacoustic cells made of insulating material can avoid floating potentials and following partial discharge. This paper studied the feasibility of insulating material-based photoacoustic cells. First, the influence of the material on the performance of photoacoustic cells was studied, and potential problems of photoacoustic cells made of insulating material quartz were discussed. Then, using COMSOL Multiphysics, the theoretical performance of quartz photoacoustic cells was simulated from both the thermal and acoustic sides. Finally, a detection system based on quartz photoacoustic cells was established to testify to the simulation outcome. The simulation results indicated that quartz-based photoacoustic cell was as capable as the conventional brass photoacoustic cell to detect trace gas quantitatively. Besides, the detection limit of the established detection system in this word could reach the level of 0.16 μL·L-1, which could meet the relevant standard. Therefore, such insulating material-based photoacoustic cell is with the potential for in-situ detection of bushing.
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Received: 2022-07-04
Accepted: 2023-06-04
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Corresponding Authors:
ZHANG Guo-qiang
E-mail: zhanggqi@mail.iee.ac.cn
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[1] XIAO Tian-wei, ZHANG Qiang, HUANG Yan-guang, et al(肖天为, 张 强, 黄炎光, 等). Power System Technology(电网技术),2015,39(6):1719.
[2] JI Sheng-chang, ZHONG Li-peng, LIU Kai, et al(汲胜昌, 钟理鹏, 刘 凯, 等). Proceedings of the CSEE(中国电机工程学报),2015,35(9):2318.
[3] Chen Tunan, Ma Fengxiang, Zhao Yue, et al. Optik (Stuttg), 2021, 243: 167440.
[4] Chen Tunan, Ma Fengxiang, Zhao Yue, et al. Sens. Rev., 2022, 42(1): 70.
[5] Sergio Bustamante, Mario Manana, Alberto Arroyo, et al. Sensors (Switzerland), 2019, 19: 4057.
[6] MA Feng-xiang, TIAN Yu, CHEN Ke, et al(马凤翔, 田 宇, 陈 珂, 等). Acta Optica Sinica(光学学报),2020,40(7):0730003.
[7] Rück T, Bierl R, Matysik F M. Sensors Actuators A: Phys., 2017, 263: 501.
[8] CHENG Gang, CAO Yuan, LIU Kun,et al(程 刚, 曹 渊, 刘 锟, 等). Acta Physica Sinica(物理学报),2019,68(7):074202.
[9] Berggren M, Bernland A, Noreland D. J. Comput. Phys., 2018, 371: 633.
[10] CHEN Wei-gen, LIU Bing-jie, ZHOU Heng-yi, et al(陈伟根, 刘冰洁, 周恒逸, 等). Transactions of China Eletrotechnical Society(电工技术学报),2010,25(11):15.
[11] TANG Ju, FAN Min, QIU Yin-jun, et al(唐 炬, 范 敏, 裘吟君, 等). High Voltage Engineering(高电压技术),2012,38(11):2919.
[12] CHENG Gang, CAO Ya-nan, TIAN Xing, et al(程 刚, 曹亚南, 田 兴, 等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2020,40(8):2345.
[13] State Grid(国家电网公司). Technical Specification for Energized Device of Electrical Equipment Part 4: Technical Specification for Energized Device of Gased Dissolved in Oil (Photoacoustic Spectrometry Method)(电力设备带电检测仪器技术规范第4-2 部分:油中溶解气体分析带电检测仪器技术规范(光声光谱法)), 2015.
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