Characteristic of rich-mixture ignition kernel driven by nanosecond repetitive pulsed discharge

Plasma-assisted ignition is a promising technology to improve engine performance. Nanosecond repetitive pulsed discharge is widely used in plasma-assisted ignition owing to its chemical activations and thermal and hydrodynamic expansions. However, the influence of ultrafast heating and hydrodynamic...

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Bibliographic Details
Published in:Science China. Technological sciences 2016, Vol.59 (1), p.109-116
Main Authors: Lin, BingXuan, Wu, Yun, Li, YiWen, Jia, Min, Zong, HaoHua, Ding, Jian, Li, YingHong
Format: Article
Language:English
Subjects:
Engineering
内核
混合
点火技术
特性
电驱动
等离子体辅助
纳秒级
重复脉冲
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Summary:Plasma-assisted ignition is a promising technology to improve engine performance. Nanosecond repetitive pulsed discharge is widely used in plasma-assisted ignition owing to its chemical activations and thermal and hydrodynamic expansions. However, the influence of ultrafast heating and hydrodynamic effects on the development of the rich-mixture ignition kernel is largely unknown. The present study aims to illustrate these effects using electrical and schlieren measurement. The number and the frequency of discharge pulses are exactly controlled to establish the relationship among the discharge energy, frequency, and rich-mixture ignition-kernel characteristics. The evolution of the ignition kernel in the early stage is mainly dominated by the discharge energy and frequency, i.e., a greater energy and a higher frequency yield a larger ignition kernel. Moreover, the influence of both the energy and frequency on the ignition kernel gradually disappears as the ignition kernel develops. According to the experimental data and theoretical analysis, the calculated laminar burning velocity is 0.319 m/s with a Markstein length of 13.43±0.11 cm when the voltage is 5.9 k V, the frequency is 3 k Hz, and the equivalence ratio is 1.3. This result indicates that the rich-mixture flame is stable in the early stage of ignition.
ISSN:1674-7321
1869-1900
DOI:10.1007/s11431-015-5950-9