Turbulence–flame interactions in lean premixed hydrogen: transition to the distributed burning regime
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Publication:2891755
DOI10.1017/jfm.2011.164zbMath1241.76435OpenAlexW2104828129MaRDI QIDQ2891755
Andrew Aspden, John B. Bell, Marcus S. Day
Publication date: 15 June 2012
Published in: Journal of Fluid Mechanics (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1017/jfm.2011.164
Related Items (14)
A DNS study of the physical mechanisms associated with density ratio influence on turbulent burning velocity in premixed flames ⋮ Validation of a mixture-averaged thermal diffusion model for premixed lean hydrogen flames ⋮ A scaling analysis for the evolution of small-scale turbulence eddies across premixed flames with implications on distributed combustion ⋮ DNS assessment of relation between mean reaction and scalar dissipation rates in the flamelet regime of premixed turbulent combustion ⋮ A computationally-efficient, semi-implicit, iterative method for the time-integration of reacting flows with stiff chemistry ⋮ Semi-implicit iterative methods for low Mach number turbulent reacting flows: operator splitting versus approximate factorization ⋮ Assessing diffusion model impacts on enstrophy and flame structure in turbulent lean premixed flames ⋮ Modelling of the turbulent burning velocity based on Lagrangian statistics of propagating surfaces ⋮ Towards the distributed burning regime in turbulent premixed flames ⋮ Influence of molecular transport on burning rate and conditioned species concentrations in highly turbulent premixed flames ⋮ Statistics conditioned to isoscalar surfaces in highly turbulent premixed reacting systems ⋮ Implications of laminar flame finite thickness on the structure of turbulent premixed flames ⋮ A priori analysis of sub-grid variance of a reactive scalar using DNS data of high Ka flames ⋮ Mesh convergence for turbulent combustion
Cites Work
- Analysis of implicit LES methods
- An adaptive Cartesian grid method for unsteady compressible flow in irregular regions
- Approximate Projection Methods: Part I. Inviscid Analysis
- Turbulent transport in flames
- The equations of motion for thermally driven, buoyant flows
- The turbulent burning velocity for large-scale and small-scale turbulence
- Turbulent Combustion
- Numerical simulation of laminar reacting flows with complex chemistry
- A Numerical Method for the Incompressible Navier-Stokes Equations Based on an Approximate Projection
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