Abstract
This study analyzes different strategies of plasma actuation of premixed swirl flames at pressures up to 3 bar. A wide range of applied voltages and pulse repetition frequencies (PRF) is considered, resulting in different combinations of nanosecond repetitively pulsed (NRP) discharge regimes, NRP glow and NRP spark discharges. Electrical characterization of the discharges is performed, measuring voltage and current, and deposited energy and power are evaluated. The effectiveness of the plasma actuation is assessed through images of OH* chemiluminescence from the flame. From these images, the distance of the center of gravity of the flame to the burner plate is evaluated, with and without plasma actuation. The results show that strategies which involve a high percentage of NRP sparks are effective at improving flame anchoring at atmospheric pressure, while they are detrimental at higher pressures. Therefore, high applied voltage and low PRF are preferable at atmospheric pressure, while the opposite is observed at elevated pressures. Moreover, it is found that a ratio of plasma power to thermal power of the flame around 1% is the best compromise between a strong actuation of the flame and a reasonable deposited electrical power. Explanations for these results are proposed.
Highlights
Introduction ce pte cri ptImproving combustion efficiency and reducing pollutant emissions in combustion systems such as gas turbine engines are major challenges that the scientific community is currently facing
Discharges have been utilized to improve the stability of various types of flames, including lean premixed swirl flames that are widely used in gas turbine combustors [2,3,4,5,6,7,8,9,10,11,12]
The efficiency of plasma actuation of premixed swirl flames by nanosecond repetitively pulsed (NRP) discharges has been investigated at pressure up to 3 bar
Summary
Improving combustion efficiency and reducing pollutant emissions in combustion systems such as gas turbine engines are major challenges that the scientific community is currently facing. In this context, burning fuels in lean premixed condition and at elevated pressure is a strategy widely utilized. These burning conditions have limitations, such as unstable combustion and flame blow-off [1]. In [11], Kim and Cohen showed that the lean blow-off limit of methaneair jet flames could be extended by NRP plasma discharges at pressures up to 5 bar
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