High-Frequency Electric Field Induced Nonlinear Electron Transport in Chiral Carbon Nanotubes

We investigate theoretically the high frequency complex conductivity in carbon nanotubes that are stimulated axially by a strong inhomogeneous electric field of the form E(t)=E0+E1cos(ωt). Using the kinetic approach based on Boltzmann’s transport equation with constant relaxation time approximation and the energy spectrum of the electron in the tight-binding approximation, together with Bhatnagar-Gross-Krook collision integral, we predict high-frequency nonlinear effects along the axial and the circumferential directions of the carbon nanotubes that may be useful for the generation of high frequency radiation in the carbon nanotubes.

Measurement of Breakdown Electric Field Strength for Vegetation and Hydrocarbon Flames

A significant number of fire-induced power disruptions are observed in several countries every year. The faults are normally phase-to-phase short circuiting or conductor-to-ground discharges at mid-span region of the high-voltage transmission system. In any case, the wildfire plumes provide a conductive path. The electrical conductivity is due to intense heat in combustion zone of the fire which creates ion and electrons from flame inherent particulates. Increase in the ion concentration increases the electrical conductivity of the fire plume. The main purpose of this study was to measure dielectric breakdown electric field for vegetation and hydrocarbon flames. The experimental data is needed for validation of simulation schemes which are necessary for evaluation of power grid systems reliability under extreme wildfire weather conditions. In this study, hydrocarbon and vegetation fuels were ignited in a cylindrically shaped steel burner which was fitted with type-K thermocouples to measure flame temperature. The fuels consisted of dried weeping wattle (Peltophorum africanum) litter, butane gas and candle wax. Two pinned copper electrodes supported by retort stands were mounted to the burner and energized to a high voltage. This generated a strong electric field sufficient to initiate dielectric breakdown in the flames. Breakdown electric field strength (Ecrit) obtained from the experiment decreased from 10.5 to 6.9 kV/cm for the flames with temperature range of 1003 to 1410 K, respectively.

心室辅助装置瞬时高功率能量电磁骚扰评价方法和平台研究

目的为了便于开展心室辅助装置抗扰性能评价,本文提出研制高功率瞬时能量(磁场、电场)骚扰抗扰测试平台。方法对于高频磁场,采用高功率变压设计与高频线圈制造技术,设计与制作谐振电路,结合信号源与高速双极性电源,搭建电磁骚扰抗扰性测试平台。高频磁场产生的干扰频率可覆盖高频电刀的典型工作频率范围,同时降低了对高速双极性电源输出功率指标的要求。对于高频电场,采用耦合线圈用于实现高频升压。结果实测数据显示,在100~1000kHz范围内,测试平台可产生最高2598A/m的高频磁场,可产生最高402.9倍的升压增益,可以实现高达5000V的高频电压,可有效评估被测产品的高频电场抗扰性能。结论该测试平台可对心室辅助装置分别开展高频磁场、高频电场、高频传导电流干扰的抗扰性测试,有利于科学有效地评价心室辅助装置的高频高功率骚扰抗扰性能,有助于形成合理的心室辅助装置电磁兼容质量评价规范。

无刷电动舵机功率驱动电路发热特性分析

针对小型大功率无刷电动舵机由于大电流、高功率密度引起的散热困难问题,开展其功率驱动电路发热特性研究。根据所使用的H-PWM-L-ON型半桥调制模式,分析了IGBT三相桥式功率逆变电路的功率损耗,基于RC热网络模型方法建立了该电路的热传导模型,并使用英飞凌FS50R06W1E3型功率模块开展了功率驱动电路发热特性仿真分析和实验验证。结果表明,所给出的功率驱动电路功率损耗分析结果合理可信,通过该热传导模型可有效计算功率器件工作温度。在无刷电动舵机设计过程中,可使用此方法进行功率器件工作温度计算,在确保低于最高工作结温的情况下提高可用输出功率。

等离子体中高频场对电导率的影响

该文详细探讨了等离子体的电导率在高频调制场的作用下，产生反常电阻的情况．通过求解双流体方程组和Ｚａｋｈａｒｏｖ方程，得到了电导率的解析表示．

磁旋弧中等离子体电导率的研究

通过半解析分析研究了外磁场对电弧等离子体电导率的影响。采用修正的洛仑兹碰撞项来描述电子之间的相互作用，从而避免了由线性化Ｆｏｋｋｅｒ－Ｐｌａｎｃｋ碰撞项带来数学上的复杂性。文中以氩等离子体为例，计算结果表明在低温范围内，磁场使欧姆电导率明显地减小，当Ｂ为０．１５Ｔ时，σｘ的值比无磁场时减小约１个数量级，而在高温情况下，电导率几乎不受磁场的影响。

空间飞行器诱发的密度空穴、高频场包络及电双层腔子

利用数值计算方法,选取二维三分量的泊松分布为初始扰动横场,研究了空间飞行器穿入电离层所引起的非线性效应,得到了密度、场及电势的演化图。结果显示,在飞行器远尾区形成了密度空穴、高频场包络及电双层三种坍塌腔子。研究这些效应对探测隐身飞行器以及预防电双层对飞行器造成的危害具有一定的意义。

高频交流SDBD约化场强对等离子体粒子演化的影响

基于高频交流激励,为获得电源参数对SDBD空间约化场强分布和等离子体组分数密度的影响规律,首先基于电势求解方程和边界条件,数值模拟了激励器空间约化场强分布,然后采用零维等离子体动力学模型,计算了不同电场参数下放电产物组分数密度的演化过程。结果表明:较强的约化场强主要集中在暴露电极与地电极之间,并向周围快速衰减降低,随着激励电压的提高,同一点约化场强线性增大;在交流激励下,约化场强随激励电压同样周期性变化,但存在微小迟滞,激励频率的变化对约化场强峰值存在明显影响;相对于激励频率,约化场强对放电产物数密度的影响更为明显;具体地,改变激励频率时,若约化场强不变,O原子数密度随激励频率呈缓慢连续增大趋势,文中1~30 kHz的增幅为3.7%;若考虑约化场强影响,O原子随激励频率呈明显倒"U"形变化,其中7 kHz时数密度最大,相比1 kHz增大了14.2%。

高频高压电场对甲烷预混倒置焰锥火焰的影响与分析

采用平面火焰燃烧器实现了一种甲烷预混倒置焰锥抬升火焰,在没有发生放电击穿的条件下着重分析了高频高压电场对火焰的影响。实验观测发现倒置焰锥火焰的抬升高度受高频高压电场的增强而降低,并且焰锥夹角随电压的增加而减小。对照实验现象分析,结果表明由于高频高压电场带来的离子风效应较小,高频高压电场对火焰面中电子或离子参与的化学反应碰撞的增强可能是最主要的原因。