TY - JOUR
T1 - Direct numerical simulation of premixed flame boundary layer flashback in turbulent channel flow
AU - Gruber, A.
AU - Chen, J. H.
AU - Valiev, D.
AU - Law, Chung King
N1 - Funding Information:
The work at SINTEF has been supported by the BIGCCS Centre, performed under the Norwegian research program Centres for Energy Efficient Research. The authors acknowledge the following partners for their contributions: Aker Solutions, ConocoPhilips Skandinavia AS, Det Norske Veritas AS, Gassco AS, Hydro Aluminium AS, Shell Technology AS, Statkraft Development AS, StatoilHydro Petroleum AS, TOTAL E&P Norge AS and the Research Council of Norway (grant numbers 178004/I30 and 176059/I30). Computational support for this project was provided by, and this research used the resources of, the National Center for Computational Sciences at Oak Ridge National Laboratory, which is supported by the office of Science of the US Department of Energy under contract DE-AC05-00OR22725. The work at Sandia National Laboratories was supported by the Division of Chemical Sciences, Geosciences, and Biosciences, Office of Basic Energy Sciences of the US Department of Energy and by the Combustion Energy Frontier Research Center. SNL is a multiprogramme laboratory operated by Sandia Corporation, a Lockheed Martin Company for the US DOE under Contract DE-AC04-94AL85000. The work at Princeton University was also supported by the Combustion Energy Frontier Research Center of the US Department of Energy.
PY - 2012/10
Y1 - 2012/10
N2 - Direct numerical simulations are performed to investigate the transient upstream propagation (flashback) of premixed hydrogen-air flames in the boundary layer of a fully developed turbulent channel flow. Results show that the well-known near-wall velocity fluctuations pattern found in turbulent boundary layers triggers wrinkling of the initially flat flame sheet as it starts propagating against the main flow direction, and that the structure of the characteristic streaks of the turbulent boundary layer ultimately has an important impact on the resulting flame shape and on its propagation mechanism. It is observed that the leading edges of the upstream-propagating premixed flame are always located in the near-wall region of the channel and assume the shape of several smooth, curved bulges propagating upstream side by side in the spanwise direction and convex towards the reactantside of the flame. These leading-edge flame bulges are separated by thin regions of spiky flame cusps pointing towards the product side at the trailing edges of the flame. Analysis of the instantaneous velocity fields clearly reveals the existence, on the reactant side of the flame sheet, of backflow pockets that extend well above the wall-quenching distance. There is a strong correspondence between each of the backflow pockets and a leading edge convex flame bulge. Likewise, high-speed streaks of fast flowing fluid are found to be always colocated with the spiky flame cusps pointing towards the product side of the flame. It is suggested that the origin o the formation of the backflow pockets, along with the subsequent mutual feedback mechanism, is due to the interaction of the approaching streaky turbulent flow pattern with the Darrieus-Landau hydrodynamic instability and pressure fluctuations triggered by the flame sheet. Moreover, the presence of the backflow pockets, coupled with the associated hydrodynamic instability and pressure-flow field interaction, greatly facilitate flame propagation in turbulent boundary layers and ultimately results in high flashback velocities that increase proportionately with pressure.
AB - Direct numerical simulations are performed to investigate the transient upstream propagation (flashback) of premixed hydrogen-air flames in the boundary layer of a fully developed turbulent channel flow. Results show that the well-known near-wall velocity fluctuations pattern found in turbulent boundary layers triggers wrinkling of the initially flat flame sheet as it starts propagating against the main flow direction, and that the structure of the characteristic streaks of the turbulent boundary layer ultimately has an important impact on the resulting flame shape and on its propagation mechanism. It is observed that the leading edges of the upstream-propagating premixed flame are always located in the near-wall region of the channel and assume the shape of several smooth, curved bulges propagating upstream side by side in the spanwise direction and convex towards the reactantside of the flame. These leading-edge flame bulges are separated by thin regions of spiky flame cusps pointing towards the product side at the trailing edges of the flame. Analysis of the instantaneous velocity fields clearly reveals the existence, on the reactant side of the flame sheet, of backflow pockets that extend well above the wall-quenching distance. There is a strong correspondence between each of the backflow pockets and a leading edge convex flame bulge. Likewise, high-speed streaks of fast flowing fluid are found to be always colocated with the spiky flame cusps pointing towards the product side of the flame. It is suggested that the origin o the formation of the backflow pockets, along with the subsequent mutual feedback mechanism, is due to the interaction of the approaching streaky turbulent flow pattern with the Darrieus-Landau hydrodynamic instability and pressure fluctuations triggered by the flame sheet. Moreover, the presence of the backflow pockets, coupled with the associated hydrodynamic instability and pressure-flow field interaction, greatly facilitate flame propagation in turbulent boundary layers and ultimately results in high flashback velocities that increase proportionately with pressure.
KW - Channel flow
KW - Flames
KW - Turbulent reacting flows
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U2 - 10.1017/jfm.2012.345
DO - 10.1017/jfm.2012.345
M3 - Article
AN - SCOPUS:84883502689
SN - 0022-1120
VL - 709
SP - 516
EP - 542
JO - Journal of Fluid Mechanics
JF - Journal of Fluid Mechanics
ER -