Analysis of flame acceleration in open or vented obstructed pipes

Bychkov, Vitaly; Sadek, Jad; Akkerman, V’yacheslav

doi:10.1103/physreve.95.013111

Cited by 7 publications

(12 citation statements)

References 18 publications

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“…In addition, a unique trend is noticed for the -impact on . propagation, the oscillations agree with the modelling [35,36], experiments [34], and theory [36] of flames in channels with both ends open or vented in terms that all of the studies [35][36][37] identified steady flame propagation prior to fast acceleration. The regime of the quasi-steady propagation is also influenced by the blockage ratio α and the thermal expansion ratio Θ.…”

Section: Corrugated Flamessupporting

confidence: 81%

“…Bychkov et al [36], developed an analytical formulation for flame propagated in obstructed channels with both ends opened. The theorical formulation for inviscid flows is presented below.…”

Section: Premixed Flames In Channels With Both Ends Openmentioning

confidence: 99%

“…Likewise, the thermal expansion Θ plays a similar role, lower gas expansion, means reduced propulsion forces and as a result, reduced propagation of the flame front. The nature of the exponential acceleration was explored by comparing the simulation results with the theory developed by Bychkov for channels [36] with closely packed obstacles and both ends open. The plots of this comparison show that the theory predicts the later stage of the exponential acceleration quite better than it predicts the early phase.…”

Section: Corrugated Flamesmentioning

confidence: 99%

“…Additionally, the flame classification diagram needs to be improved using more data sets, to clearly classify the accelerating and non-accelerating regimes in obstructed channels with both ends opened. Also, the Bychkov theory for premixed flames in open channels [36] needs to be updated to incorporate the effect of gas compressibility. -APENG/(VM**2+UPENG*BPENG*VM-BPENG**2) ZF = P(K)*VM/(UG*T(K)) AMPPA = XCH4*YR*XCH4*YR*APPCH4 + XCH4*YR*XO2*YR*(1.0 -F12)* .…”

Section: Corrugated Flamesmentioning

confidence: 99%

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Propagation and Morphology of Premixed Flames in Obstructed Channels under Atmospheric and Supercritical Conditions

Adebiyi¹

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The understanding of the morphology and propagation of premixed flames in channels is vital for the design and development of efficient propulsion systems requiring high heat release, such as pulse-detonation engines, and for resolving accidental fire in industrial processes. In this dissertation, extensive computational simulations of premixed flames in channels with rectangular and cylindrical cross sections, with closely packed obstacles are carried out. The goal is to provide insights into flame propagation under various conditions, which would be invaluable to the development of next-generation energy and propulsion systems as well as fire safety of industrial processes.

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Section: Corrugated Flamessupporting

confidence: 81%

“…Bychkov et al [36], developed an analytical formulation for flame propagated in obstructed channels with both ends opened. The theorical formulation for inviscid flows is presented below.…”

Section: Premixed Flames In Channels With Both Ends Openmentioning

confidence: 99%

Section: Corrugated Flamesmentioning

confidence: 99%

Section: Corrugated Flamesmentioning

confidence: 99%

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Propagation and Morphology of Premixed Flames in Obstructed Channels under Atmospheric and Supercritical Conditions

Adebiyi¹

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“…It was suggested that the interaction of the expanded gas with the obstructed walls of the channel obstacle creates a turbulent feedback, which promotes the flame speed rapidly [11]. A similar result has been recently identified in the analytical study of FA in a vented obstructed channel by Bychkov et al [12]. The acceleration characteristics in channels with both ends open were found to be considerably weaker as compared to that in semi-open channels.…”

Section: Combustion Theory Fundamentalssupporting

confidence: 70%

Effect of Non-Equidiffusivity on Premixed Flame Propagation in Obstructed Channels

Idowu¹

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Effect of Non-Equidiffusivity on Premixed Flame Propagation in Obstructed Channels Gbolahan Idowu Continuous fire safety hazards stimulate in-depth learning and understanding of what causes an initially slow premixed flame (deflagration) front to accelerate and eventually detonate. Such flame acceleration (FA), presumably followed by a deflagration-to-detonation transition (DDT), are intriguing phenomena that have both fundamental interests and practical relevance. On one hand, it is the desire to prevent FA and DDT to avoid or, at least, mitigate unwanted explosions or fires. On the other hand, FA and DDT can be utilized, constructively, in the novel energyefficient technologies such as micro-combustors, rotation-detonation engines or pulse-detonation engines. A flame accelerates in tubes or channels, with acceleration being most intensive in obstructed pipes. The latter fact has been known for a while, but this acceleration was typically devoted to turbulence or shocks. In contrast, the Bychkov scenario of FA in channels, equipped with a toothbrush like array of tightly-packed obstacles, is shockless and conceptually laminar, with turbulence playing only a supplementary role. In spite of the laminar nature, this FA is extremely strong and leads to DDT.

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