1) single-electrode tip discharge
单电极尖端放电
1.
Using the experimental NO removal system with single-electrode tip discharge structure, the NO reduction characteristics of N_2-NO system were revealed to guide the engineering practice.
利用新型低能耗N2—NO系统单电极尖端放电等离子体NOx还原试验系统,得到了对实际多电极放电等离子体NOx脱除有指导意义的还原特性。
2) tip discharge
尖端放电
1.
On the base of the charge distributing rule on the cone-shaped conductor and micro-mechanism of the tip discharge,simulation research on radiation field of tip discharge is investigated in this paper.
本文在分析锥形导体的电荷分布规律及尖端放电微观机理的基础上,对尖端放电进行了仿真研究,结论与实验基本一致。
3) point discharge
尖端放电
1.
TiN permeation layers composed of diffusion and deposition layers are synthesized on the surface of carbon steel using plasma point discharge, hollow cathode effect and reactive vapor deposition techniques.
利用等离子尖端放电、空心阴极效应和反应气相沉积技术,在碳钢表面形成具有扩散层和沉积层的Ti N渗镀层,然后在此渗镀层表面沉积(PVD法)TiB2薄膜,形成Ti N/TiB2复合渗镀层。
2.
A new technique of TiN multi-permeation layers composed of diffusion and deposition layers on the surface of carbon steel by using plasma point discharge, hollow cathode effect and reactive vapor deposition at the same time are introduced.
介绍了一种同时利用等离子尖端放电、空心阴极效应和反应气相沉积技术,在碳钢表面形成具有扩散层和沉积层的TiN复合渗镀层新工艺技术。
3.
Tradition says that the principle of operation of lightning rod is point discharge.
避雷针工作原理的传统说法是尖端放电,现在看来这种说法是不确切的,下面从避雷针工作原理的演示实验出发以及从大量的事实来论述避雷针工作原理的实质。
4) point electrode
尖端电极
5) point corona discharge
尖端电晕放电
1.
The radiation signal was sampled by using the point corona discharge simulation system,and the characteristics of the signal in time-domain and frequency-domain were analyzed to analyse the corona discharge characte ristic of radiation signal better.
为了更好地分析电晕放电辐射信号的特征,笔者利用尖端电晕放电模拟测试系统采集了电晕放电辐射信号数据,研究分析了信号在时域和频域的一些特性。
6) corona point
电晕放电尖端
补充资料:尖端放电
尖端放电 point discharge 带电导体尖端附近空气中的放电现象。静电平衡时,带电导体外附近的场强与导体的面电荷密度成正比。大致说来,导体表现凸出而尖锐的地方,即曲率较大的尖端,电荷密集,面电荷密度增大,附近的场强特别强,致使空气电离,产生放电现象。尖端放电时,在它周围往往隐隐地笼罩着一层光晕,叫做电晕。高压输电线附近发生的尖端放电会造成能量损耗,需使输电线表面光滑,以避免尖端放电。避雷针则利用尖端放电,将集中的高空电荷通过接地装置泄入大地,以免建筑物等遭雷击。 |
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
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