Flame Propagation from the Closed End of an Open-ended Tube: an analysis of the effects of fuel type, tube length, and equivalence ratio and an insight into flame dynamics

Gray, Joshua; Moeck, Jonas P.; Paschereit, C. O.

doi:10.2514/6.2013-3656

Cited by 2 publications

(2 citation statements)

References 15 publications

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“…Two propagation modes are also seen here as previously reported. In two cases, extreme deceleration of the flame is observed due to the "tulip flame" phenomenon [18], a type of Rayleigh-Taylor instability, and subsequent coupling with the acoustic modes of the tube [19,20]. In the remaining cases, the flame does not exhibit said deceleration and continues to moderately accelerate.…”

Section: Resultsmentioning

confidence: 99%

Effects of Nanosecond Repetitively Pulsed Plasma Discharges on a Propagating Hydrogen--Air Flame

Gray

Lacoste

2019

AIAA Scitech 2019 Forum

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Pressure-gain combustion cycles have been a topic of intense scientific research in recent years. Pulse detonation combustors are one promising technology for successfully implementing these pressure-gain cycles. These combustors frequently rely on obstacles for accelerating a propagating flame and inducing the deflagration-to-detonation transition. The use of obstacles, however, has several disadvantages. Replacing such obstacles with nanosecond repetitively pulsed plasma discharges may be advantageous to developing this technology further. Proof of concept has been achieved demonstrating the effectiveness of this strategy at enhancing the transition to detonation. This work is a closer investigation into the effect of these plasma discharges on flames with varying turbulence intensities and propagation velocities. For velocities below 200 m/s, the effect is minimal and transition to detonation does not occur. The effect of plasma discharges on flame acceleration also begins to diminish for the current configuration and pulse repetition frequency at speeds above 400 m/s. This give a range where nanosecond repetitively pulsed plasma discharges may be used effectively for efficient flame acceleration and transition to detonation.

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Section: Resultsmentioning

confidence: 99%

Effects of Nanosecond Repetitively Pulsed Plasma Discharges on a Propagating Hydrogen--Air Flame

Gray

Lacoste

2019

AIAA Scitech 2019 Forum

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“…In numerical simulations of flame propagation assuming non-reflecting boundary conditions [28], oscillations due to flame inversion were identified showing that there is an additional source of oscillations different from acoustic feedback in these type of configurations. Furthermore, in [35], the authors compared predicted modes of oscillations due to acoustics with experimental results and found discrepancies that were attributed to the assumed reflection/transmission coefficients. On the other hand, the work in [34], showed that the observed oscillations depend on tube length and sound speed, showing a clear influence of acoustics.…”

Section: Front Velocity and Accelerationmentioning

confidence: 99%

Flame propagation and acceleration in narrow channels: sensitivity to facility specific parameters

2021

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Flame propagation experiments in stoichiometric H 2 -air are conducted in a smooth 482-mm long, 10-mm × 10-mm square cross section channel, closed at the ignition end and open at the opposite end. Direct observation is used to track the flame acceleration dynamics. The effect of facility specific parameters (i.e. ignition energy, boundary conditions near the ignition end, window material and settling time between filling and ignition) on flame propagation and acceleration is assessed. The absolute mean deviation is used as a metric to determine the effect of the aforementioned parameters on the collected front position data, and Response Surface Methods for experimental design is applied to examine inter-parameter interactions. Results show that the boundary conditions near the ignition end (i.e. large/small ignition offset) have the largest influence on the recorded front position with the remaining parameters playing a less important role. The early stages of flame propagation is compared against theoretical predictions to understand the discrepancies observed in the data; a simple acoustic model was found sufficient to explain the increased acceleration rates observed for the large ignition offset cases. Finally, a link between the observed front oscillations during flame acceleration and the flow rate dynamics at the channel's open end is highlighted.

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Flame Propagation from the Closed End of an Open-ended Tube: an analysis of the effects of fuel type, tube length, and equivalence ratio and an insight into flame dynamics

Cited by 2 publications

References 15 publications

Effects of Nanosecond Repetitively Pulsed Plasma Discharges on a Propagating Hydrogen--Air Flame

Effects of Nanosecond Repetitively Pulsed Plasma Discharges on a Propagating Hydrogen--Air Flame

Flame propagation and acceleration in narrow channels: sensitivity to facility specific parameters

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