高压直流输电工程电触发换流阀TE板烧毁机理研究

doi:10.11930/j.issn.1004-9649.201810028

摘要/Abstract

摘要： 高压直流换流阀晶闸管电子板（Thyristor Electronics Board，TE 板）是高压直流输电工程换流阀中重要的设备，如在运维过程中出现TE板烧毁，将导致换流阀极停运，严重影响直流工程的安全运行。针对天广直流TE板电阻器烧毁进行分析，首先对TE板进行外观检查和电性能检测，采用X射线、扫描声学显微镜等方法确认元器件内部电路受损范围，确认各受损元器件所属TE板功能模块，分析TE板故障元器件烧毁原因，探讨了TE板烧毁机理，并通过实验对TE板烧毁故障过程进行重现，验证分析结论，最终得出TE板烧毁原因，该分析方法对高压直流输电工程类似板卡故障原因分析具有重要参考意义。

关键词: 高压直流输电, 换流阀, TE板, X射线检查, 电路原理分析

Abstract: Thyristor electronic board (TE board) of HVDC converter valve is an important equipment of HVDC converter valve. In the process of operation and maintenance, TE board burned out many times, resulting in the shutdown of the converter valve pole, which affects the safe operation of HVDC project seriously. This paper studies the TE board resistor burnout event in Tian-Guang HVDC project. Firstly, the appearance and electrical performance of TE plate are inspected. The damaged area of internal circuit of components is confirmed by X-ray detection and scanning acoustic microscopy, and the function modules of TE board which belong to each damaged component are also confirmed. Then, the burning reason of TE board faulty components is analyzed by circuit principle method, and the burning mechanism of TE board is speculated. The process of TE board burning failure is reproduced through experiments to verify the assumed mechanism for TE board burnout. Finally, the cause of TE board burning is obtained. The analysis method has reference significance for the analysis of similar board failure in HVDC project.

Key words: HVDC, converter valve, TE board, X-ray detection, circuit principle analysis

王振, 刘坤, 鞠伟. 高压直流输电工程电触发换流阀TE板烧毁机理研究[J]. 中国电力, 2020, 53(5): 56-62.

WANG Zhen, LIU Kun, JU Wei. Study on Burnout Mechanism of TE Board for HVDC Transmission Project Electric Triggered Converter Valve[J]. Electric Power, 2020, 53(5): 56-62.

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链接本文: https://www.electricpower.com.cn/CN/10.11930/j.issn.1004-9649.201810028

https://www.electricpower.com.cn/CN/Y2020/V53/I5/56

参考文献

[1] 卢亚军, 宋胜利, 肖鲲, 等. 特高压直流工程阀控通用接口技术[J]. 中国电力, 2017, 50(2): 34–39
LU Yajun, SONG Shengli, XIAO Kun, et al. General interface technology of valve control system in UHVDC project[J]. Electric Power, 2017, 50(2): 34–39
[2] 中国南方电网超高压输电公司. 高压直流设备基础[M]. 北京: 中国电力出版社, 2011: 180.
[3] 才利存, 常忠廷, 李娟. ±800kV/6 250A锡盟—泰州直流输电工程换流阀合成运行试验[J]. 中国电力, 2016, 49(11): 20–24, 69
CAI Licun, CHANG Zhongting, LI Juan. Thyristor valve synthetic operational test of ±800kV/6 250A Ximeng-Taizhou UHVDC project[J]. Electric Power, 2016, 49(11): 20–24, 69
[4] 王华昕, 蓝元良, 汤广福. 限流器晶闸管阀自触发保护动作电压阈值设计[J]. 高电压技术, 2011, 37(7): 1811–1817
WANG Huaxin, LAN Yuanliang, TANG Guangfu. Design on thyristor self-trigger protection action voltage threshold of series resonance fault current limiter[J]. High Voltage Engineering, 2011, 37(7): 1811–1817
[5] 袁青云. HVDC换流阀及其触发与在线监测系统[M]. 北京: 中国电力出版社, 1999.
[6] 白光亚. 光触发晶闸管换流阀技术及其应用[J]. 高电压技术, 2004, 30(11): 55–56, 59
BAI Guangya. Light triggered thyristor and its application[J]. High Voltage Engineering, 2004, 30(11): 55–56, 59
[7] 宁凤辉, 赵中原, 邱毓昌. 三峡至常州±500kV高压直流输电用晶闸管阀技术特点[J]. 高压电器, 2003, 39(4): 62–63, 69
NING Fenghui, ZHAO Zhongyuan, QIU Yuchang. Technique features of thyristor valve used for ±500 kV HVDC transmission from the Three Gorges to Changzhou[J]. High Voltage Apparatus, 2003, 39(4): 62–63, 69
[8] 周亮, 汤广福, 郝长城, 等. 换流阀阀基电子设备丢脉冲保护与控制的研究[J]. 电网技术, 2011, 35(7): 222–226
ZHOU Liang, TANG Guangfu, HAO Changcheng, et al. Research on control and protection of missing firing pulses for valve basic electronics[J]. Power System Technology, 2011, 35(7): 222–226
[9] 黄义隆, 陈欢, 国建宝, 等. 天广直流换流阀异常导通EMTDC仿真分析[J]. 电力系统保护与控制, 2017, 45(3): 125–130
HUANG Yilong, CHEN Huan, GUO Jianbao, et al. Analysis on the abnormal breakover of the converter valve based on EMTDC simulation in Tian-Guang HVDC project[J]. Power System Protection and Control, 2017, 45(3): 125–130
[10] 刘飞, 卢志良, 刘燕, 等. 用于TCR的晶闸管光电触发与监测系统[J]. 高电压技术, 2007, 33(6): 123–128
LIU Fei, LU Zhiliang, LIU Yan, et al. Thyristor photoelectric firing and monitoring system applied to TCR[J]. High Voltage Engineering, 2007, 33(6): 123–128
[11] 明菊兰, 李海燕, 余璐静, 等. 能量色散X射线荧光光谱法检测抗燃油氯含量的研究[J]. 中国电力, 2017, 50(4): 130–134
MING Julan, LI Haiyan, YU Lujing, et al. Detection of chlorine content in phosphate ester fire-resistant fluids using energy dispersive X-ray fluorescence spectrometry method[J]. Electric Power, 2017, 50(4): 130–134
[12] 李兴旺, 邬剑. 基于X射线数字成像系统的10 kV穿墙套管缺陷检测分析[J]. 广东电力, 2013, 26(5): 101–103, 106
LI Xingwang, WU Jian. Analysis on 10 kV wall bushing defect detection based on X radial digital imaging system[J]. Guangdong Electric Power, 2013, 26(5): 101–103, 106
[13] 向真, 张欣, 黄荣辉, 等. X射线数字成像技术在开关设备缺陷诊断中的应用[J]. 高压电器, 2016, 52(2): 195–199
XIANG Zhen, ZHANG Xin, HUANG Ronghui, et al. Application of X-ray digital radiography in the defect diagnosis of switchgears[J]. High Voltage Apparatus, 2016, 52(2): 195–199
[14] 黄帆, 邓昌义, 杨通高, 等. 快堆含镎燃料棒环焊缝X射线检查工艺研究[C] ]//中国核学会2015年学术年会论文集. 绵阳: 2015: 311-317.
[15] 陈章涛, 潘凌宇. 声学扫描显微镜检查在塑封器件检测中的应用[J]. 电子与封装, 2013, 13(3): 9–12
CHEN Zhangtao, PAN Lingyu. The application of scanning acoustic microscope inspect in PEM test[J]. Electronics & Packaging, 2013, 13(3): 9–12
[16] 尹颖, 朱卫良. 塑封器件无损开封技术介绍[J]. 电子与封装, 2009, 9(9): 12–15, 19
YIN Ying, ZHU Weiliang. Introduction of non-destructive decapsulate technology for plastic encapsulated microchips[J]. Electronics & Packaging, 2009, 9(9): 12–15, 19
[17] 侯小利. 塑封器件化学开封方法优化设计研究[J]. 科研, 2017, 10(2): 1–3
HOU Xiao-li. A Study On The Optimization Design For The Plastic Package Devices Chemical Decapsulation[J]. Scientific Research, 2017, 10(2): 1–3
[18] 王振, 钱海, 周尚礼, 等. 天广直流工程换流阀异常导通原因分析及对策[J]. 高电压技术, 2017, 43(7): 2154–2160
WANG Zhen, QIAN Hai, ZHOU Shangli, et al. Cause analysis and countermeasures for the abnormal conduction of converter valve in Tian-Guang HVDC project[J]. High Voltage Engineering, 2017, 43(7): 2154–2160
[19] Siemens. Valve Base Electronics Maintenance Manual(EB4.112.TZ.)[Z] Germany: Siemens, 1999: 25-27.
[20] Siemens. Thyristor Electronics Board Maintenance Manual (EB4.111-2.TZ.l)[Z]. Germany: Siemens, 1999: 3-4.