Effects of pulse rise time and repetition frequency on nanosecond pulsed plasma ignition for combustion

IF 1.3 Q3 ORTHOPEDICS

Plasma Research Express Pub Date : 2021-03-01 DOI:10.1088/2516-1067/ab880a

David Alderman, Christopher Tremble, D. Singleton, J. Sanders, C. Jiang

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引用次数: 7

Abstract

Transient plasma ignition (TPI) employs highly non-equilibrium plasmas driven by nanosecond high-voltage pulses for combustion ignition. The effects of rise time and pulse repetition frequency (PRF) on combustion ignition are evaluated when transient plasmas, powered by 10-ns, kilovolt pulses, are employed to initiate combustion of lean, stoichiometric, or rich methane-dry air mixtures at atmospheric pressure. It was found that the plasmas driven by high voltage pulses with a faster rise time and PRF between 6–10 kHz enhanced combustion with higher peak pressure and/or shorter ignition delay. A mode transition in the plasma, corresponding to the combustion initiation, was observed based on voltage and current waveforms of four consecutive pulsed plasmas driven by a pulse burst at kilohertz PRFs. Although benefits in combustion ignition from a shorter rise time and optimal PRF were observed for all three equivalence mixture ratios, the highest peak pressure and shortest ignition delay were associated with the stoichiometric mixtures. In addition, the gas temperature of the transient plasma was measured by determining the rotational temperature of the 2nd positive system of nitrogen to be ∼1000 K for the first pulse and increased up to 2000 K after the application of the 4th pulse in a four-pulse burst TPI.

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脉冲上升时间和重复频率对纳秒脉冲等离子体点火燃烧的影响

瞬态等离子体点火技术是利用纳秒级高压脉冲驱动高度非平衡等离子体进行燃烧点火。当瞬态等离子体在大气压下由10ns，千伏脉冲驱动，启动稀薄、化学计量或富含甲烷-干空气混合物的燃烧时，评估了上升时间和脉冲重复频率(PRF)对燃烧着火的影响。结果表明，在上升时间较快、PRF在6 ~ 10 kHz之间的高压脉冲驱动等离子体时，燃烧峰值压力增大，点火延迟缩短。基于脉冲脉冲爆发驱动的四个连续脉冲等离子体的电压和电流波形，观察到等离子体中的模式转变，对应于燃烧的开始。虽然在所有三种等效混合比例下，较短的上升时间和最佳的PRF都有利于燃烧点火，但最高的峰值压力和最短的点火延迟与化学计量混合物有关。此外，瞬态等离子体的气体温度通过测定第一个脉冲时氮的第二个正极系统的旋转温度为~ 1000 K，在四脉冲爆发TPI中应用第四个脉冲后增加到2000 K来测量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Plasma Research Express Energy-Nuclear Energy and Engineering

CiteScore

2.60

自引率

0.00%

发文量