容性高压脉冲放电系统及其在触发地震实验研究中的意义

doi:10.3969/j.issn.0253-4967.2018.06.016

摘要/Abstract

摘要： 稳定的触发放电系统设计方案是实验室研究触发地震的基础技术之一。文中以金属丝电爆炸法为基础，利用开关电源和自愈式高压脉冲电容器，设计了1套高压脉冲充放电系统。经过实验测试，可实现以下功能：1）高压充电电源系统的电压和电流自主调节，并可在充电完成后进行关断安全保护；2）采用遥控和手动2种控制方式，控制高压电容的充电、释电和触发脉冲放电，其中无线遥控方式大幅提高了断层失稳实验的可操作性及安全性；3）多路触发TTL信号同步输出，实现多系统协同工作，为各观测系统提供对时信号；4）多组气体放电管控制触发放电，可控放电电压范围在500～5000V内可调；5）实时输出放电电压与电流，有利于监测放电过程。总之，新设计的充、放电系统，不仅可以实现目前触发地震实验研究的要求，还可用于静态、动态载荷下触发应力扰动实验，进而通过主动触发实验检验断层系统的稳定性。

关键词: 高压电容器, 充放电, 电爆炸, 动态监测, 触发地震

Abstract: An external small disturbance may trigger seismic events when the fault is in a critical state. The problems related with earthquakes triggered by the dynamic stress such as blasting loads, impact loads, volcanic eruptions and strong earthquakes, have usually drawn wide concerns in earthquake science, and the corresponding research contents are quite extensive, including earthquake triggering mechanisms, triggering earthquake uncertainty, aftershock triggering, and so on. Among them, experimental research is an important way to understand the stress triggering conditions and physical mechanisms, such as the influence of load disturbance on fault friction traits, the influence of periodic disturbance of tidal stress on fault instability, etc., all of which can be gained through experimental investigations. Among them, "how to trigger" is a basic scientific problem to increase the understanding of earthquake prediction theory, thus receiving more attention. There are also some studies that focus on "what happened after the trigger", that is, the sliding instability generated by the triggering method, and then the evolution characteristics of the sliding instability process. The well-known experimental study of the super-shear rupture process is conducted by using the electric explosion method to trigger the fault instability, and the high-speed camera records the super-shear rupture during the fault instability. This means that when the trigger source is controllable, it is possible to generate different types of instability processes, and then to explore which earthquakes will be triggered at different time and space positions under different stress states by means of active triggering. The study of stability analysis and instability process has important scientific significance.A stable system of capacitive high-voltage pulse discharge and recharge is one of basic techniques for studying the triggered earthquakes in laboratory. Based on the wire electric explosion method, this paper develops a controllable trigger experiment system. By designing a new capacitive high-voltage pulse charge and discharge system, while considering the actual needs of monitoring and system timing, multiple functions are integrated into one system. Functionally, in addition to realizing the dynamic loading and unloading function of the wire electric explosion method, the discharge process can be monitored, and the triggering, synchronization and timing signal output is performed with other observation systems, thus realizing the whole process monitoring of the dynamic disturbance action. After testing, the following functions are achieved:1)The voltage and current of the high-voltage charging power supply system can be automatically adjusted, and the system can be shut off after charging; 2)Control modes include manual and remote controls. These two modes can control the recharge, release and pulse discharge of the high voltage capacitor; 3)The system can produce multi-channel synchronous output, which satisfy multiple systems working together. In particular, the remote sensing method greatly improves the experimental maneuverability and security; 4)The system has multiple sets of gas discharge tube to trigger discharge, with a wide range of discharge voltage of 500~5 000V; 5)Roche coil resistance integral current detection can meet the transient resistance, large current detection. Test results indicate that this system has good repeatability and stability with the same discharge energy and discharge energy regulator, which is conducive to carry out single channel trigger of high-pressure discharge experiment. In short, the new charging and discharging system can meet the requirements of experimental study of triggering earthquake. In addition, this system can be used to generate the stress disturbance under certain static and dynamic conditions, and then judge whether this kind of mechanical conditions in active fault systems is currently stable.In short, a controllable single-shot discharge system is developed by a capacitive high-voltage pulse discharge system, which provides a good technical basis for experimental research on triggering earthquakes. In addition, the new system also has application significance:1)multiple triggering output can simultaneously start multiple systems and improve the efficiency of observation. Fault instability is a characteristic of transient response, so, its observation requires high-speed acquisition equipment, which is difficult to control on observation; the trigger system is controllable, with active synchronization observation using physical parameters; 2)stress disturbance can be triggered under static and dynamic loads to detect the safety and stability of the fault system with active trigger.

Key words: high-voltage condense, recharge-discharge, wire exploding, dynamic monitoring, earthquake triggering

中图分类号:

P315.8

张智河, 郭彦双, 陈顺云. 容性高压脉冲放电系统及其在触发地震实验研究中的意义[J]. 地震地质, 2018, 40(6): 1417-1426.

ZHANG Zhi-he, GUO Yan-shuang, CHEN Shun-yun. A SYSTEM OF CAPACITIVE HIGH-VOLTAGE PULSE RECHARGE/DISCHARGE AND ITS IMPLICATION ON EXPERIMENTALLY TRIGGERED EARTHQUAKE[J]. SEISMOLOGY AND GEOLOGY, 2018, 40(6): 1417-1426.

参考文献

郭增建, 韩延本, 吴瑾冰. 2001. 从震源物理角度讨论外因对地震的触发机制［J］. 国际地震动态, (5):13-16. GUO Zeng-jian, HAN Yan-ben, WU Jin-bing. 2001. Discussion on earthquake triggering mechanism by external factors from the angle of earthquake source physics［J］. Recent Developments in World Seismology, (5):13-16(in Chinese).
何孟兵, 李涛, 吴国华, 等. 2009. 两电极气体火花开关触发系统［J］. 强激光与粒子束, 21(6):951-955. HE Meng-bing, LI Tao, WU Guo-hua, et al. 2009. Trigger system of two-electrode gas spark switch［J］. High Power Laser and Particle Beams, 21(6):951-955(in Chinese).
黄元敏, 马胜利. 2008. 关于应力触发地震机理的讨论［J］. 地震, 28(3):95-102. HUANG Yuan-min, MA Sheng-li. 2008. Discussion on mechanism of earthquake triggering by stress［J］. Earthquake, 28(3):95-102(in Chinese).
黄元敏, 马胜利, 缪阿丽, 等. 2016. 正应力扰动对断层滑动失稳影响的实验研究［J］. 地球物理学报, 59(3):931-940. HUANG Yuan-min, MA Sheng-li, MIAO A-li, et al. 2016. Effect of normal stress perturbation on frictional instability:An experimental study［J］. Chinese Journal of Geophysics, 59(3):931-940(in Chinese).
雷兴林, 马胜利, 闻学泽, 等. 2008. 地表水体对断层应力与地震时空分布影响的综合分析; 以紫坪铺水库为例［J］. 地震地质, 30(4):1046-1064. LEI Xing-lin, MA Sheng-li, WEN Xue-ze, et al. 2008. Integrated analysis of stress and regional seismicity by surface loading:A case study of Zipingpu reservoir［J］. Seismology and Geology, 30(4):1046-1064(in Chinese).
李祥超, 周中山, 陈璞阳, 等. 2017. 多间隙气体放电管研究及其应用［J］. 电工技术学报, 32(2):70-76. LI Xiang-chao, ZHOU Zhong-shan, CHEN Pu-yang, et al. 2017. Study and application of the multi-gap for gas discharge［J］. Transactions of China Electrotechnical Society, 32(2):70-76(in Chinese).
李晓昂, 刘轩东, 曾凡辉, 等. 2014. 电极熔蚀导致的气体火花开关绝缘子性能劣化［J］. 强激光与粒子束, 26(7):271-275. LI Xiao-ang, LIU Xuan-dong, ZENG Fan-hui, et al. 2014. Degradation of gas switch insulator due to electrode erosion［J］. High Power Laser and Particle Beams, 26(7):271-275(in Chinese).
刘轩东, 沈曦, 李晓昂, 等. 2017. 脉冲作用下气体火花开关电极熔蚀研究［J］. 高电压技术, 43(9):3070-3077. LIU Xuan-dong, SHEN Xi, LI Xiao-ang, et al. 2017. Researches on electrode erosion of gas spark switch under pulsed current［J］. High Voltage Engineering, 43(9):3070-3077(in Chinese).
马瑾. 2010. 地震机理与瞬间因素对地震的触发作用:兼论地震发生的不确定性［J］. 自然杂志, 32(6):311-313, 318. MA Jin. 2010. Uncertainty of the earthquakes and earthquake mechanism and seismic triggering effect of instantaneous factors［J］. Chinese Journal of Nature, 32(6):311-313, 318(in Chinese).
万永革, 吴忠良, 周公威, 等. 2002. 地震应力触发研究［J］. 地震学报, 24(5):533-551. WAN Yong-ge, WU Zhong-liang, ZHOU Gong-wei, et al. 2002. Research on seismic stress triggering［J］. Acta Seismologica Sinica, 24(5):533-551(in Chinese).
万永革, 沈正康, 尚丹. 2006. 2005年10月巴基斯坦M_W7.6地震对余震的触发研究［J］. 中国地震, 22(3):277-286. WAN Yong-ge, SHEN Zheng-kang, SHANG Dan. 2006. Study on triggering effect of the October, 2005 Pakistan M_W7.6 earthquake on its aftershocks［J］. Earthquake Research in China, 22(3):277-286(in Chinese).
王坤, 史宗谦, 石元杰, 等. 2017. 真空及空气中金属丝电爆炸特性研究［J］. 物理学报, 66(18)185-203. WANG Kun, SHI Zong-qian, SHI Yuan-jie, et al. 2017. Characteristics of electrical explosion of single wire in a vacuum and in the air［J］. Acta Physica Sinica, 66(18):185-203(in Chinese).
王莹. 2016. 触发型气体放电管试验研究与分析［J］. 电瓷避雷器, 272(4):51-55. WANG Ying. 2016. Study and application of the trigger type gas discharge［J］. Insulators and Surge Arresters, 272(4):51-55(in Chinese).
薛伟, 郑丽君, 高云广, 等. 2015. 电力电子变压器中高频变压器的设计方法［J］. 电测与仪表, 52(23):117-121. XUE Wei, ZHENG Li-jun, GAO Yun-guang, et al. 2015. Design of high frequency transformer applied in the power electronic transformer［J］. Electrical Measurement & Instrumentation, 52(23):117-121(in Chinese).
杨华运. 2016. 不同温湿度条件下静电火花放电实验研究［J］. 煤炭技术, 35(7):169-170. YANG Hua-yun. 2016. Experimental study on electrostatic discharge under different temperatures and humidities［J］. Coal Technology, 35(7):169-170(in Chinese).
张建新, 赵建沛, 吴盛刚, 等. 2015. 百万伏级高压可控点火球装置的设计及其放电特性探讨［J］. 高压电器, 51(12):184-189. ZHANG Jian-xin, ZHAO Jian-pei, WU Sheng-gang, et al. 2015. Design and discharge characteristic discussion of 1000 kV controllable high-voltage ignition ball［J］. High Voltage Apparatus, 51(12):184-189(in Chinese).
张仁豫, 陈昌渔, 王昌长. 2003. 高电压试验技术［M］. 2版. 北京:清华大学出版社。ZHANG Ren-yu, CHEN Chang-yu, WANG Chang-chang. 2003. High Voltage Test Techniques［M］. 2nd ed. Beijing:Tsinghua University Press(in Chinese).
张永民, 邱爱慈, 周海滨, 等. 2016. 面向化石能源开发的电爆炸冲击波技术研究进展［J］. 高电压技术, 42(4):1009-1017. ZHANG Yong-min, QIU Ai-ci, ZHOU Hai-bin, et al. 2016. Research progress in electrical explosion shockwave technology for developing fossil energy［J］. High Voltage Engineering, 42(4):1009-1017(in Chinese).
周海滨, 张永民, 刘巧珏, 等. 2017. 铜丝电爆炸等离子体对含能材料的驱动特性［J］. 高电压技术, 43(12):4026-4031. ZHOU Hai-bin, ZHANG Yong-min, LIU Qiao-jue, et al. 2017. Ignition performance of Cu-wire electrical explosion plasma on energetic materials［J］. High Voltage Engineering, 43(12):4026-4031(in Chinese).
Lockner D A, Beeler N M. 1999. Premonitory slip and tidal triggering of earthquakes［J］. Journal of Geophysical Research, 104(B9):133-150.
Lei X, Huang D, Su J, et al. 2017. Fault reactivation and earthquakes with magnitudes of up to M_W4.7 induced by shale gas fracking in the Sichuan Basin, China［J］. Scientific Reports, 7(1):7971.
Lu X, Rosakis A J, Lapusta N. 2010. Rupture modes in laboratory earthquakes:Effect of fault prestress and nucleation conditions［J］. Journal of Geophysical Research, 115:B12302.
Rubino V, Rosakis A J, Lapusta N. 2017. Understanding dynamic friction through spontaneously evolving laboratory earthquakes［J］. Nature Communications, 8:15991.
Xia K, Rosakis A J, Kanamori H. 2004. Laboratory earthquakes:The sub-Rayleigh-to-supershear rupture transition［J］. Science, 303(5665):1859-1861.
Xia K, Rosakis A J, Kanamori H, et al. 2005. Laboratory earthquakes along inhomogeneous faults:Directionality and supershear［J］. Science, 308(5722):681-684.
Xie C, Lei X, Zhao X, et al. 2017. Tidal triggering of earthquakes in the Ning'er area of Yunnan Province, China［J］. Journal of Asian Earth Sciences, 138:477-483.

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