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华北电力大学 数理学院,河北 保定,071003
纸质出版日期:2018-4-5,
网络出版日期:2017-9-18,
收稿日期:2017-7-25,
修回日期:2017-8-24,
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唐蕾, 王永杰, 袁春琪等. 三种电极的大气压氩等离子体射流光学特性[J]. 发光学报, 2018,39(4): 547-554
TANG Lei, WANG Yong-jie, YUAN Chun-qi etc. Optical Property of The Atmospheric Pressure Argon Plasma Jet Generated by Three Types of Electrodes[J]. Chinese Journal of Luminescence, 2018,39(4): 547-554
唐蕾, 王永杰, 袁春琪等. 三种电极的大气压氩等离子体射流光学特性[J]. 发光学报, 2018,39(4): 547-554 DOI: 10.3788/fgxb20183904.0547.
TANG Lei, WANG Yong-jie, YUAN Chun-qi etc. Optical Property of The Atmospheric Pressure Argon Plasma Jet Generated by Three Types of Electrodes[J]. Chinese Journal of Luminescence, 2018,39(4): 547-554 DOI: 10.3788/fgxb20183904.0547.
采用铜片-单匝线圈电极、螺旋缠绕电极和双铜片电极3种结构的放电装置,以氩气作为工作气体,在正弦波激励下获得了大气压等离子体射流。利用电学方法测量了放电电流以及电荷量,并对放电脉冲和放电功率进行了研究;利用发射光谱法对射流的等离子体参量进行了空间分辨测量,并根据ArⅠ 763.5 nm和Ar Ⅰ 772.4 nm的光强计算了电子激发温度。结果发现:在外加电压的正负半周期内,电流脉冲的个数和幅值呈现非对称的变化趋势;随着外加电压的增加,3种结构电极的放电功率从1.7 W逐渐增加到6.0 W;在相同的外加电压情况下,电极面积越小,等离子体射流的长度越长;3种等离子体射流的电子激发温度在1 348.5~3 212.1 K之间,并且随着气体流量的增加,各位置的电子激发温度总体上呈下降趋势,而等离子体的电子密度呈上升趋势。实验结果表明:外加电压对放电功率有一定影响;射流长度与电极面积有关;气体流量对电子激发温度和电子密度的空间分布起重要作用。
The atmospheric argon plasma jet generated by three kinds of electrode configurations was obtained
and the discharge characteristics of the plasma jet were investigated by electrical and optical methods. First
the discharge current and quantity of electric charge were measured by electrical method simultaneously. Meanwhile
the discharge pulse and average discharge power were investigated. The plasma parameters of the plasma jet were studied by spatial resolved optical emission spectroscopy. In addition
the excited electron temperature was estimated by spectral intensity of ArⅠ 763.5 nm and ArⅠ 772.4 nm. It is found that the discharge current pulses are asymmetric at different discharge phases. With the increase of the applied voltage
the discharge powers of the three electrodes are increased from 1.7 W to 6.0 W. At the same applied voltage
the smaller the area of the electrode is
the longer the length of the plasma jet becomes. Besides the above results
we also found that the excited electron temperature decreases from 3 212.1 K to 1 348.5 K with the increase of the gas flow rate
while the electron density of the plasma jet decreases with the gas flow rate. The experimental results show that the applied voltage has some influence on the discharge power and the length of jet is related to the electrode area. The gas flow rate plays an important role in the excited electron temperature and the spatial distribution of electron density.
等离子体射流电极结构放电功率电子激发温度电子密度
plasma jetelectrode configurationdischarge powerexcited electron temperatureelectron density
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