Simulation of Front Propagation at Large Non-dimensional Flow Disturbance Intensities

Zhu, Jianqin; Ronney, Paul D.

doi:10.1080/00102209408935452

Cited by 40 publications

(20 citation statements)

References 30 publications

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“…Their result UT ~-exp(U/Uw) (6) agrees well with their experiments (Fig. 4) and numerical simulations [37,38]. Furthermore, this concept of the role of island formation on UT is supported by the analysis of Joulin and Sivashinsky [39].…”

Section: Flame Stretch Effectssupporting

confidence: 81%

Some open issues in premixed turbulent combustion

Ronney

Modeling in Combustion Science

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The widely studied subject of premixed turbulent combustion is discussed, with particular attention to identification and review of controversial and unresolved fundamental issues having practical significance. Four such topics are discussed: (1) prediction of turbulent burning velocity (ST) in the flamelet regime, (2) the role of the velocity spectrum on ST, (3) the existence and properties of turbulent combustion with distributed reaction zones, and (4) quenching of flames by turbulence. Directions for future research are suggested.

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Section: Flame Stretch Effectssupporting

confidence: 81%

Some open issues in premixed turbulent combustion

Ronney

Modeling in Combustion Science

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“…This produces what is termed "square vortices" by Helenbrook & Law (1999). A similar flow field is applied by Vladimirova et al (2003) who name it "cellular flow" and also Zhu & Ronney (1994) use a flow with cellular vortices to study flame propagation in it. The particular flow has the advantage of being very simple -ideally containing only one Fourier mode.…”

Section: Simulation Setupmentioning

confidence: 99%

The cellular burning regime in type Ia supernova explosions

Röpke

Hillebrandt²,

Niemeyer³

2004

A&A

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Abstract. We investigate the interaction of thermonuclear flames in Type Ia supernova explosions with vortical flows by means of numerical simulations. In our study, we focus on small scales, where the flame propagation is no longer dominated by the turbulent cascade originating from large-scale effects. Here, the flame propagation proceeds in the cellular burning regime, resulting from a balance between the Landau-Darrieus instability and its nonlinear stabilization. The interaction of a cellularly stabilized flame front with a vortical fuel flow is explored applying a variety of fuel densities and strengths of the velocity fluctuations. We find that the vortical flow can break up the cellular flame structure if it is sufficiently strong. In this case the flame structure adapts to the imprinted flow field. The transition from the cellularly stabilized front to the flame structure dominated by vortices of the flow proceeds in a smooth way. The implications of the results of our simulations for Type Ia Supernova explosion models are discussed.

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“…These include work on semiconductor manufacturing [2-4, 35, 76, 84], geometry and minimal surfaces [9,[22][23][24]72], combustion and detonation [10,32,63,105,106], fluids and surface-tension-driven flows [15, 19, In Fig. 8, we give a perspective on how some of these topics are related.…”

Section: Three Applicationsmentioning

confidence: 99%