一种静电放电模拟装置的设计
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摘要
近年来,与静电放电(ESD)领域相关联的气体放电理论、材料科学和电测技术等新兴学科的不断研究和发展,已逐渐由实验科学阶段走向实际应用阶段。同时,人们也逐渐发现静电放电给人类造成的危害是十分惊人的,它不仅能够影响人类的正常生活,更是限制了自动化生产水平的提高。基于传统静电放电的模拟装置设备单一、功能局限,无法满足静电放电全方位、多用途的实验要求,为解决这一问题,设计和实现了包含电极模拟、方位变换、电路传输的完整的实验模拟装置。该装置主要由底座、支撑架、金属球、放电针、绝缘环、方位表盘等6部分组成,能够满足不同极化方向电磁场条件下的实验要求,同时还能够实现对不同高度、不同位置条件下的电磁场的基本极化方向进行判断识别。该系统具有一定的实验创新性和先进性,能够有效地满足各类电磁实验的需要,为研究电磁诱发静电放电实验提供了有力的硬件支持。
In recent years,the research and development of gas discharge theory,material science and electrical measurement technology,which are related to the field of electrostatic discharge(ESD),have gradually moved from the experimental stage to the practical stage.At the same time,people have gradually found that the harm caused by ESD to human beings is very alarming.It can not only affect the normal life of human beings,but also limit the improvement of automation production level.Based on traditional electrostatic discharge the simulator with single equipment and limited function,can not meet the all-round and multi-purpose experimental requirements of electrostatic discharge.To solve this problem,a complete experimental simulator including electrode simulation,azimuth conversion and circuit transmission was designed and implemented.The device is mainly composed of six parts:base,support frame,metal ball,discharge needle,insulating ring and azimuth dial.It can meet the experimental requirements of electromagnetic field in different polarization directions,and also can judge and identify the basic polarization direction of electromagnetic field in different altitudes and positions.The system is innovative and advanced,and provides powerful hardware support for the study of electromagnetic induced electrostatic discharge experiments.
In recent years,the research and development of gas discharge theory,material science and electrical measurement technology,which are related to the field of electrostatic discharge(ESD),have gradually moved from the experimental stage to the practical stage.At the same time,people have gradually found that the harm caused by ESD to human beings is very alarming.It can not only affect the normal life of human beings,but also limit the improvement of automation production level.Based on traditional electrostatic discharge the simulator with single equipment and limited function,can not meet the all-round and multi-purpose experimental requirements of electrostatic discharge.To solve this problem,a complete experimental simulator including electrode simulation,azimuth conversion and circuit transmission was designed and implemented.The device is mainly composed of six parts:base,support frame,metal ball,discharge needle,insulating ring and azimuth dial.It can meet the experimental requirements of electromagnetic field in different polarization directions,and also can judge and identify the basic polarization direction of electromagnetic field in different altitudes and positions.The system is innovative and advanced,and provides powerful hardware support for the study of electromagnetic induced electrostatic discharge experiments.
引文
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[2]张书锋,柴昊,周玉新,等.超高速碰撞太阳电池阵诱发放电效应的实验研究[J].爆炸与冲击,2016,36(3):386-390.(Zhang Shufeng,Chai Hao,Zhou Yuxin,et al.Experimental study on the induced discharging effect of ultrahigh-speed collision solar array.Explosion and Shock Waves,2016,36(3):386-390)
[3]李宏伟,韩建伟,蔡明辉,等.激光诱导等离子体模拟微小空间碎片撞击诱发放电研究[J].物理学报,2014,63(11):470-475.(Li Hongwei,Han Jianwei,Cai Minghui,et al.Laser-induced plasma simulation of small space debris impact-induced discharges.Acta Physica Sinica,2014,63(11):470-475)
[4]李宏伟,韩建伟,蔡明辉,等.微小空间碎片撞击诱发放电效应研究[J].物理学报,2013,62(22):464-471.(Li Hongwei,Han Jianwei,Cai Minghui,et al.Effect of micro-space debris impact-induced discharge.Acta Physica Sinica,2013,62(22):464-471)
[5]惠健.一种模拟教室门无线监控辅助教学装置的设计[J].中小企业管理与科技,2018(4):125-126.(Huijian.Design of an auxiliary teaching device for wireless monitoring of analog classroom doors.Management and Technology of Small and Medium-sized Enterprises,2018(4):125-126)
[6]武智慧,钱建平,牛公杰.一种排气式膛压模拟装置[J].爆炸与冲击,2018,38(6):1181-1188.(Wu Zhihui,Qian Jianping,Niu Gongjie.An exhaust chamber pressure simulator.Explosion and Shock Waves,2018,38(6):1181-1188)
[7]李志刚,王声波,郭大浩,等.强激光引导和诱发大气高压放电研究[J].激光技术,1999(6):332-334.(Li Zhigang,Wang Shengbo,Guo Dahao,et al.Study on the guidance and induced atmospheric high voltage discharge by high power laser.Laser Technology,1999(6):332-334)
[8]蒋锴.一种离子发射航天器电位主动控制方法[C]//中国物理学会第二十届全国静电学术会议论文集.2015:187-191.(Jiang Kai.An active potential control method for ion launch spacecraft//Proceedings of the 20th National Electrostatic Academic Conference of the Chinese Physical Society.2015:187-191.)
[9]何墨渊,冯文全,张杰斌.一种小型化抗干扰导航接收机的系统设计[J].导航定位学报,2019(1):93-97.(He Moyuan,Feng Wenquan,Zhang Jiebin.System design of a miniaturized anti-jamming navigation receiver.Journal of Navigation and Positioning,2019(1):93-97)
[10]高奔,韩佩彤,石光达,等.一种基于并联机构的航天器姿态模拟装置的设计开发[J].机械设计,2018,35(12):93-98.(Gao Ben,Han Peitong,Shi Guangda,et al.Design and development of a spacecraft attitude simulator based on parallel mechanism.Mechanical Design,2018,35(12):93-98)
[11]刘永智,解立强,李海翼,等.一种高低压输电传输模拟实验装置设计[J].自动化与仪器仪表,2017(2):170-171.(Liu Yongzhi,Xie Liqiang,Li Haiyi,et al.Design of a simulation experimental device for high and low voltage transmission.Automation and instrumentation,2017(2):170-171.
[12] Ge Weiqing,Pickar J G.Change of paraspinal muscle spindle resting discharge evoked by mechanical vibration[C]//IEEE 27th Annual International Conference of the Engineering in Medicine and Biology Society.2005.
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