等离子体加热

  • 网络plasma heating
等离子体加热等离子体加热
  1. a-Si∶H薄膜固相晶化法制备多晶硅薄膜氢等离子体加热法晶化a-Si∶H薄膜

    Polycrystalline silicon film obtained by solid-phase crystallization of a-Si : H film A study of poly-silicon fims prepared by hydrogen plasma heating

  2. 此外,在磁约束核聚变装置中,实现等离子体加热的方法主要是中性束加热,而当前中性束系统中所应用的离子源就是ICP源。

    In addition , in the neutral beam injection system , which is the mainly method for plasma heating in the magnetic confinement fusion , the ICP source is also chosen as the ion source .

  3. 采用氢等离子体加热的方法晶化a-Si:H薄膜制备多晶硅薄膜,用Raman散射谱和傅里叶变换红外吸收谱(FT-IR)等方法进行表征和分析。

    Polysilicon thin films have been obtained by hydrogen plasma heating of a-Si : H films deposited by PCVD . The films were characterized and analyzed by Raman and FT-IR spectra .

  4. DJR-7型等离子体加热装置的研究与应用

    The Research and Applications of DJR-7 Type Plasma Heating Device

  5. 该文利用Arrhenius一级反应动力学模型来研究生物质闪速热解挥发特性。为了研究闪速加热条件下生物质的热解挥发特性,设计了等离子体加热高温层流炉作为实验设备。

    A kinetic Arrhenius first-order rate model was used to investigate biomass flash pyrolysis volatilization characteristics in this paper . A plasma heated laminar entrained flow reactor was designed and built in our lab.

  6. 分别使用频率为34.34GHz和20.1GHz的回旋管系统从外侧和顶端注入微波,对CT-6B托卡马克等离子体加热,均观察到明显的加热效果。

    Obvious heating effects have been observed in RF heating experiments on CT-6B tokamak , in which microwave beams of frequencies 34.34 GHz and 20.1 GHz generated by two gyrotron systems were launched from top and outside of the device , respectively .

  7. 等离子体加热中间罐技术在我国的应用及前景

    Application & prospect of plasma heating tundish technology in China

  8. 等离子体加热流化床反应器的设计与实验

    Design and Experimental Study of Fluidized Bed Heated by Plasma Flow Jet

  9. 玉米秸秆在等离子体加热流化床上的快速热解液化研究

    Fast pyrolysis of corn stalk for bio-oil in a plasma heated fluidized bed

  10. 磁镜装置中等离子体加热的实验研究

    The experimental investigation on the properties of the plasma heated by waves in the mirror machine

  11. 为研究闪速加热条件下生物质的热解挥发特性,设计了等离子体加热高温层流炉作为实验设备。

    An investigation on the devolatilization characteristics of pulverized corn stalk at fast heating rate in a laminar furnace ;

  12. 研究等离子体加热和粒子加速问题,是等离子体物理和等离子体天体物理中的重要课题。

    Both the heating of plasma and the acceleration of particles are important topics in plasma physics and plasma astrophysics .

  13. 耀斑过程涉及能量释放、等离子体加热、粒子加速、物质运动、波动等现象。

    The eruption of a solar flare involves energy release , plasma heating , particle acceleration , mass flows , waves , etc. .

  14. 等离子体加热的物理机制为:大量的电子在基频共振层吸收微波,并在此处反弹。

    The physics mechanism of the plasma heating is that alot of electrons absorb the microwave and turn back near the resonance zone .

  15. 它在毫米波雷达、受控热核聚变等离子体加热和诊断、定向能武器以及材料处理等领域有重大应用前景。

    Potential applications of the gyrotron include millimeter wave radar , plasma heating and diagnostic of controlled thermonuclear fusion , directed-energy weapons and materials processing .

  16. 进而分析这种相互作用所导致的等离子体加热现象和反常输运现象,最后对相对论效应的修正也进行了一些探讨。

    The anomalous transport and wave-heating phenomena resulted from the cyclotron trapping resonance as well as the relativistic effects on the resonance condition are also discussed .

  17. 高功率毫米亚毫米波源,在雷达、等离子体加热、高能加速器、通信等方面有着重要的应用前景,一直以来受到各国的重视。

    High-power radiation sources in millimeter and sub-millimeter waves have a great prospect of applications to radar , plasma heating , high-gradient linear colliders , and communications , and therefore , attract more and more attention in many countries .

  18. 回旋管具有在毫米、亚毫米波段其他器件无可比拟的高峰值功率、高平均功率的优越性,因此在等离子体加热、受控热核聚变、雷达、通信及电子对抗等方面都有着广阔的应用前景。

    Gyrotron has the superiorities , high peak power and high average power . So Gyrotron is vastly applied in many areas , such as plasma heating , controlled thermonuclear fusion ( CTF ), radar , communication , electron countermeasure .

  19. 观察到欠热模式下金属蒸汽的多次喷发现象,由此提出二次加热机制,即焦耳加热和等离子体加热。

    More than one times of the vapor burst from a titanium wire exploding in the mode of underheat were usually observed , which suggested there exist two heating mechanisms , i.e. , Joule heating followed by the plasma heating .

  20. 由于日冕环可以储存更多的剪切场或扭转场的磁能,释放这部分磁能就可以驱动日冕环运动产生日冕瞬变过程,或者使环内的等离子体加热或加速而产生太阳耀斑。

    More magnetic energy of shear or twisted magnetic field may be stored in the loop , the corona loop will be driven to produce the corona transient process or the plasma will be heated or accelerated to produce solar flares if part of the stored energy is released .

  21. 采用研制的大体积射频等离子体红外加热化学气相沉积设备,在600℃的低温下,在5cm×5cm大的Ni片上生长出碳纳米管薄膜。

    The carbon nanotubes thin film grown on the surface of 5cm × 5cm Ni plate substrate was obtained at 600 ℃ temperature by using large volume radio frequency plasma enhanced infrared thermal chemical vapor deposition equipment developed by ourselves .

  22. 在HL1M托卡马克上进行的电子回旋共振加热实验表明,在低等离子体密度加热过程中,产生大量的超热电子。

    Experimental results of electron cyclotron resonant heating in the HL-1M tokamak show that a large number of superthermal electrons appear during ECRH .

  23. 场反向等离子体环加热和转移实验

    Heating and translating experiments of the field reversed plasma toroid

  24. 直流非转移弧热等离子体喷枪加热效率分析

    Research on the thermal efficiency of a DC non-transfer arc plasma torch

  25. 高功率微波对等离子体限幅器加热效应分析土星低能热等离子体

    Thermal Effect of Plasma Limiter Induced by High Power Microwave

  26. 高强度超短脉冲激光等离子体真空加热的粒子模拟

    Particle Simulation of Vacuum Heating in Plasmas Produced by an Ultrashort Laser Pulse

  27. CF-Ⅱ等离子体环加热和注入实验

    Heating and injection experiments of the CF-II plasma to-roid

  28. 最后介绍了等离子体电弧加热熔融垃圾灰的开发现状。

    Finally , the present status of melting of ash from incinerators by Plasma arc heating is introduced .

  29. 当激光强度较高时,非线性逆轫致吸收是对等离子体的加热起重要作用的机制。

    The nonlinear inverse bremsstrahlung absorption is a main mechanism in the plasma heating at laser plasma interaction .

  30. 首先结合拼焊板的结构特点以及等离子体弧加热区与热影响区尺寸,建立差厚拼焊板的有限元模型并划分不均匀的有限元网格。

    Firstly , the paper established the finite element model of different thickness TWB and divided the geometric model into non-uniform finite element mesh combining the structural characteristics of TWB . the plasma arc heating zone and heat-affected zone were also considered .