Exploring streamer variability in experiments

Reactivity of Solids Pub Date : 2007-12-01 DOI:10.6100/IR631104

T. Briels

{"title":"Exploring streamer variability in experiments","authors":"T. Briels","doi":"10.6100/IR631104","DOIUrl":null,"url":null,"abstract":"The goal of this experimental investigation is to systematically explore di®erences in streamers under a large variety of conditions; this will form a basis on which theory can be tested and developed. Streamers are narrow, rapidly growing, weakly ionized channels. They can be created by applying a high voltage over a non-conducting medium such as air. Streamers are used in applications because highly reactive radicals are created in their ionizing front which are very suitable for cleaning purposes in water and gas (e.g. killing of bacteria, removal of phenol, NOx, SO2, °y ash, odor and tar). Also, in the ignition of so called high intensity discharge lamps streamers are found. Although streamers show up in many desired or undesired places, especially at sharp tips where the electric ¯eld is enhanced, not many people have ever seen their wonderful appear- ance due to their low light intensity and short duration. They typically look like lightning but then with many more branches, like a tree. You can try to observe them in nature as sprite discharges high up in the atmosphere or as St. Elmo's ¯re on ships. The chances of hearing them are higher. They make a distinct hissing or buzzing sound as sometimes can be heard near high voltage lines. This thesis focusses on the start and propagation of primary streamers. Parameters that are changed during the experiments are the streamer polarity (positive and negative), the elec- trode distance (10-160 mm) and shape (point-plane and plane-plane), voltage amplitude (1-96 kV) and rise time (12-150 ns), pressure (13-1000 mbar) and gas (air and nitrogen). An intensi¯ed CCD-camera with a time resolution of » 2 ns is used to photograph the discharge. Current and voltage are digitized on an oscilloscope. A streamer is called positive (cathode directed) or negative (anode directed) depending on the polarity of the applied pulse (chapter 7). Time resolved photographs show that the positive and negative primary streamer propagation is built up of four stages: 1) a light emitting cloud at the electrode tip that evolves into 2) a thin expanding shell from which 3) one or more streamers emerge that 4) propagate through the gap. Positive streamers go through stages 1 to 4 for voltages V ¸ Vinception (chapter 3). The negative streamer propagation needs a minimal critical voltage to go beyond stage 2 (chapter 7). This volt- age appears to be around the DC-breakdown voltage in our experiments. The di®erences between positive and negative streamers disappear with increasing voltage as shown for streamers in a 40 mm point-plane gap in air at 1 bar: ² 5 kV 40 kV. ² Type 2 streamers are thick with a diameter of about 1.2 mm, a velocity of 0.5 mm/ns and currents of the order of 1 A. Their current density is about 2.4 A/mm2. They are created when V t 40 kV (t VDCibreakdown). ² Type 3 streamers are the thinnest streamers found. Their diameter is 0.2 mm, their velocity is » 0.1 mm/ns, their current » 10 mA and their current density is about 0.5 A/mm2. They are created when Vinception . V 60 ns) and the streamers start before the voltage has reached its maximal amplitude. In general, it seems that diameter and velocity are related since a certain diameter has a certain velocity regardless of where the streamer propagates in the gap. The streamer properties depend on the local electric ¯eld as is usually assumed in numerical models. Di®erences between positive streamers in ambient air and nitrogen (N2, purity 99.9%) in a pressure range of 13-1000 mbar are investigated in a point-plane gap (chapter 6). Positive streamers in nitrogen are 1) thinner, 2) curlier, 3) more intense and 4) less di®use than streamers in air. They also 5) branch more resulting in 6) a shorter distance D between branching events and 7) they propagate further down the electrode gap. The branches that deviate from the main channel however 8) die out closer to this channel. The measurements are used to search for experimental evidence of the theoretical expecta- tion that lengths and times scale with inverse pressure p (chapter 5 and 6). These results can be extrapolated to sprites at an altitude of 80 km in the atmosphere where the pressure is » 10i2 mbar. ² For the minimal diameter d the relation p ¢ d = 0.20 § 0.02 mm¢bar for air and p ¢ d = 0.12 § 0.02 mm¢bar for N2 is found. The estimated minimal value for sprites is 0.1-0.3 mm¢bar. ² The ratio D=d gives a value of D=d = 11.6 § 1.5 for air and D=d = 9.1 § 3.3 for N2. ² The experiments in air and N2 show that the streamer velocity v increases about 0.1-0.2 mm/ns with decreasing pressure while the scaling theory predicts that v is independent of p. Here it must be noted that the measurements are done on minimal, type 3 streamers and type 2 streamers. In a 10 mm plane-plane gap, discharges are initiated by focussing and shooting a laser on the top plate (chapter 7) when a voltage near the DC-breakdown voltage is applied. On the photographs only negative discharges that consist of a streamer and evolution to glow are seen; no positive discharges can be photographed except for sparks. This is unexpected since both polarities show a streamer peak in the current signal of similar amplitude (1- 10 mA for pressures of 100-1000 mbar). In the negative current pulse the evolution to glow is also visible while this does not exist for positive discharges. Perhaps the streamer light is too faint compared to the laserspot and only the glow is seen on the pictures. It must be noted though that primary streamers in a point-plane gap are not overexposed by laserlight when the laser is shot to the needle tip. Current and voltage evolutions in the plane-plane gap furthermore show that positive and negative streamers in N2 and air at di®erent pressures are created at a similar reduced electric ¯eld of 20 § 5 kV/(cm¢bar). This thesis gives insight into streamer start, propagation and branching behavior. Its measurements are in good agreement with various experimental results reported in the literature which makes the broad parameter study reliable and suitable for comparison with results from analytical theory and numerical simulations. The conclusion of this thesis is that there is one kind of streamer whose properties vary gradually with voltage, pressure and circuit impedance as long as measurements are done in one gas and with one polarity, where it must be noted that the di®erences between positive and negative streamers decrease with increasing voltage. When measurements are done in di®erent gases, di®erent minimal diameters, velocities, distances between branch- ing events, breakdown voltages, etc. are found. The experiments have veri¯ed that lengths scale with inverse pressure even when streamers are ignited at an electrode at (near) atmo- spheric pressure: conditions that according to theory will break the scaling law since the electrode is not scaled with pressure and the nitrogen states that emit the photons that are used for photoionization are quenched at pressures above » 40 mbar. A last conclusion is that streamers made in di®erent setups show similar patterns and diameters as long as the voltage rise time, peak voltage and internal resistance are similar.","PeriodicalId":101061,"journal":{"name":"Reactivity of Solids","volume":"1 1","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2007-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"29","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Reactivity of Solids","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.6100/IR631104","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 29

Abstract

The goal of this experimental investigation is to systematically explore di®erences in streamers under a large variety of conditions; this will form a basis on which theory can be tested and developed. Streamers are narrow, rapidly growing, weakly ionized channels. They can be created by applying a high voltage over a non-conducting medium such as air. Streamers are used in applications because highly reactive radicals are created in their ionizing front which are very suitable for cleaning purposes in water and gas (e.g. killing of bacteria, removal of phenol, NOx, SO2, °y ash, odor and tar). Also, in the ignition of so called high intensity discharge lamps streamers are found. Although streamers show up in many desired or undesired places, especially at sharp tips where the electric ¯eld is enhanced, not many people have ever seen their wonderful appear- ance due to their low light intensity and short duration. They typically look like lightning but then with many more branches, like a tree. You can try to observe them in nature as sprite discharges high up in the atmosphere or as St. Elmo's ¯re on ships. The chances of hearing them are higher. They make a distinct hissing or buzzing sound as sometimes can be heard near high voltage lines. This thesis focusses on the start and propagation of primary streamers. Parameters that are changed during the experiments are the streamer polarity (positive and negative), the elec- trode distance (10-160 mm) and shape (point-plane and plane-plane), voltage amplitude (1-96 kV) and rise time (12-150 ns), pressure (13-1000 mbar) and gas (air and nitrogen). An intensi¯ed CCD-camera with a time resolution of » 2 ns is used to photograph the discharge. Current and voltage are digitized on an oscilloscope. A streamer is called positive (cathode directed) or negative (anode directed) depending on the polarity of the applied pulse (chapter 7). Time resolved photographs show that the positive and negative primary streamer propagation is built up of four stages: 1) a light emitting cloud at the electrode tip that evolves into 2) a thin expanding shell from which 3) one or more streamers emerge that 4) propagate through the gap. Positive streamers go through stages 1 to 4 for voltages V ¸ Vinception (chapter 3). The negative streamer propagation needs a minimal critical voltage to go beyond stage 2 (chapter 7). This volt- age appears to be around the DC-breakdown voltage in our experiments. The di®erences between positive and negative streamers disappear with increasing voltage as shown for streamers in a 40 mm point-plane gap in air at 1 bar: ² 5 kV 40 kV. ² Type 2 streamers are thick with a diameter of about 1.2 mm, a velocity of 0.5 mm/ns and currents of the order of 1 A. Their current density is about 2.4 A/mm2. They are created when V t 40 kV (t VDCibreakdown). ² Type 3 streamers are the thinnest streamers found. Their diameter is 0.2 mm, their velocity is » 0.1 mm/ns, their current » 10 mA and their current density is about 0.5 A/mm2. They are created when Vinception . V 60 ns) and the streamers start before the voltage has reached its maximal amplitude. In general, it seems that diameter and velocity are related since a certain diameter has a certain velocity regardless of where the streamer propagates in the gap. The streamer properties depend on the local electric ¯eld as is usually assumed in numerical models. Di®erences between positive streamers in ambient air and nitrogen (N2, purity 99.9%) in a pressure range of 13-1000 mbar are investigated in a point-plane gap (chapter 6). Positive streamers in nitrogen are 1) thinner, 2) curlier, 3) more intense and 4) less di®use than streamers in air. They also 5) branch more resulting in 6) a shorter distance D between branching events and 7) they propagate further down the electrode gap. The branches that deviate from the main channel however 8) die out closer to this channel. The measurements are used to search for experimental evidence of the theoretical expecta- tion that lengths and times scale with inverse pressure p (chapter 5 and 6). These results can be extrapolated to sprites at an altitude of 80 km in the atmosphere where the pressure is » 10i2 mbar. ² For the minimal diameter d the relation p ¢ d = 0.20 § 0.02 mm¢bar for air and p ¢ d = 0.12 § 0.02 mm¢bar for N2 is found. The estimated minimal value for sprites is 0.1-0.3 mm¢bar. ² The ratio D=d gives a value of D=d = 11.6 § 1.5 for air and D=d = 9.1 § 3.3 for N2. ² The experiments in air and N2 show that the streamer velocity v increases about 0.1-0.2 mm/ns with decreasing pressure while the scaling theory predicts that v is independent of p. Here it must be noted that the measurements are done on minimal, type 3 streamers and type 2 streamers. In a 10 mm plane-plane gap, discharges are initiated by focussing and shooting a laser on the top plate (chapter 7) when a voltage near the DC-breakdown voltage is applied. On the photographs only negative discharges that consist of a streamer and evolution to glow are seen; no positive discharges can be photographed except for sparks. This is unexpected since both polarities show a streamer peak in the current signal of similar amplitude (1- 10 mA for pressures of 100-1000 mbar). In the negative current pulse the evolution to glow is also visible while this does not exist for positive discharges. Perhaps the streamer light is too faint compared to the laserspot and only the glow is seen on the pictures. It must be noted though that primary streamers in a point-plane gap are not overexposed by laserlight when the laser is shot to the needle tip. Current and voltage evolutions in the plane-plane gap furthermore show that positive and negative streamers in N2 and air at di®erent pressures are created at a similar reduced electric ¯eld of 20 § 5 kV/(cm¢bar). This thesis gives insight into streamer start, propagation and branching behavior. Its measurements are in good agreement with various experimental results reported in the literature which makes the broad parameter study reliable and suitable for comparison with results from analytical theory and numerical simulations. The conclusion of this thesis is that there is one kind of streamer whose properties vary gradually with voltage, pressure and circuit impedance as long as measurements are done in one gas and with one polarity, where it must be noted that the di®erences between positive and negative streamers decrease with increasing voltage. When measurements are done in di®erent gases, di®erent minimal diameters, velocities, distances between branch- ing events, breakdown voltages, etc. are found. The experiments have veri¯ed that lengths scale with inverse pressure even when streamers are ignited at an electrode at (near) atmo- spheric pressure: conditions that according to theory will break the scaling law since the electrode is not scaled with pressure and the nitrogen states that emit the photons that are used for photoionization are quenched at pressures above » 40 mbar. A last conclusion is that streamers made in di®erent setups show similar patterns and diameters as long as the voltage rise time, peak voltage and internal resistance are similar.

查看原文

微信好友朋友圈 QQ好友复制链接

本刊更多论文

探索实验中的流光变异性

本实验研究的目的是系统地探索在各种条件下的流的差异;这将形成一个基础，理论可以在此基础上进行测试和发展。流带是狭窄的、快速生长的、弱电离的通道。它们可以通过在非导电介质(如空气)上施加高电压而产生。流线在应用中使用，因为在其电离前沿产生高活性自由基，非常适合于水和气体中的清洁目的(例如杀死细菌，去除苯酚，NOx, SO2，灰，气味和焦油)。此外，在所谓的高强度放电灯的点火中发现了飘带。尽管飘带出现在许多人们想要或不想要的地方，特别是在电场增强的尖端，但由于其光强低且持续时间短，很少有人见过它们的奇妙外观。它们通常看起来像闪电，但有更多的树枝，像树一样。你可以试着在大自然中观察它们，就像精灵在大气中喷射一样，或者像圣埃尔莫的¯¯在船上一样。听到它们的几率更高。它们发出明显的嘶嘶声或嗡嗡声，有时可以在高压线附近听到。本文主要研究主流的产生和传播。实验过程中改变的参数有:流光极性(正极性和负极性)、电极距离(10-160 mm)和形状(点平面和面平面)、电压幅值(1-96 kV)和上升时间(12-150 ns)、压力(13-1000 mbar)和气体(空气和氮气)。使用时间分辨率为2ns的强化ccd相机对放电过程进行了拍摄。电流和电压在示波器上数字化。根据所施加脉冲的极性，流光被称为正(阴极定向)或负(阳极定向)(第7章)。时间分辨照片显示，正和负的主流光传播由四个阶段组成:1)电极尖端的发光云演变成2)一个薄的膨胀壳，3)一个或多个流光出现，4)通过间隙传播。在电压V δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ δ。正、负流光之间的差异随着电压的增加而消失，如图所示，流光在1 bar:²5 kV / 40 kV的空气中40 mm点平面间隙中。²2型流线厚，直径约1.2 mm，速度为0.5 mm/ns，电流约为1a。其电流密度约为2.4 A/mm2。它们是在V - 40kv(电压击穿)时产生的。2 3型拖缆是目前发现的最薄的拖缆。它们的直径为0.2 mm，速度为»0.1 mm/ns，电流»10 mA，电流密度约为0.5 A/mm2。它们是在inception时创建的。V 60 ns)，流光在电压达到最大振幅之前就开始了。一般来说，直径和速度似乎是相关的，因为一定的直径有一定的速度，而不管流在间隙中传播到哪里。流光的性质取决于局部电场，通常在数值模型中是这样假设的。在点平面间隙中，研究了在13-1000毫巴压力范围内，环境空气和氮气(N2，纯度99.9%)中正流光的Di®差异(第6章)。与空气中的流光相比，氮气中的正流光1)更薄，2)更弯曲，3)更强烈，4)Di®使用更少。它们的分支也更多，导致分支事件之间的距离D更短，并且沿着电极间隙传播得更远。然而，偏离主河道的支流在靠近主河道的地方就消失了。这些测量结果用于寻找理论预期的实验证据，即长度和时间与逆压力p成比例(第5章和第6章)。这些结果可以外推到大气中80公里高度的sprites，那里的压力为»10i2mbar。²对于最小直径d，发现对于空气p¢= 0.20§0.02 mm¢bar，对于N2 p¢= 0.12§0.02 mm¢bar的关系。精灵的估计最小值为0.1-0.3 mm / bar。²对于空气，D= D= 11.6§1.5，对于N2, D= D= 9.1§3.3。²在空气和N2中的实验表明，拖缆速度v随着压力的降低而增加约0.1-0.2 mm/ns，而标度理论预测v与p无关。这里必须注意的是，测量是在最小型、3型和2型拖缆上进行的。在10毫米的平面间隙中，当施加接近直流击穿电压的电压时，通过聚焦并在顶板上发射激光(第7章)来启动放电。在照片上，只看到由流光和演变成辉光组成的负放电;除火花外，不能拍摄正极放电。这是出乎意料的，因为两个极性在相似振幅的电流信号中显示出一个流峰(100-1000毫巴压力为1- 10毫巴)。在负电流脉冲的演变发光也是可见的，而这并不存在于正放电。也许流光是太微弱的激光光斑相比，只有辉光在图片上被看到。必须注意的是，当激光射到针尖时，点平面间隙中的主流光不会被激光过度曝光。此外，平面间隙中的电流和电压演变表明，在20§5 kV/(cm¢bar)的近似电场下，不同压力下N2和空气中的正流光和负流光会产生。本文对streamer的启动、传播和分支行为进行了深入的研究。它的测量结果与文献中报道的各种实验结果吻合良好，这使得广义参数研究可靠，适合与解析理论和数值模拟的结果进行比较。本文的结论是，只要在一种气体和一种极性下进行测量，就会发现有一类流光的性能随电压、压力和电路阻抗的变化而逐渐变化，其中必须注意的是，正流光和负流光的差值随电压的增加而减小。当在不同的气体中进行测量时，可以发现不同的最小直径，速度，分支事件之间的距离，击穿电压等。实验已经证实，即使在(接近)大气压的条件下，在电极上点燃飘带，长度也与反压力成比例:根据理论，这种情况将打破标度定律，因为电极不与压力成比例，而发射用于光电离的光子的氮态在高于40毫巴的压力下被淬灭。最后一个结论是，只要电压上升时间、峰值电压和内阻相似，在不同设置下制成的拖缆就会显示出相似的图案和直径。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文去求助

来源期刊

Reactivity of Solids

自引率

0.00%

发文量

期刊最新文献

Exploring streamer variability in experiments Subject index Author index Preface Amorphization reactions during mechanical alloying/milling of metallic powders