Cellular structure of explosion flames: Modeling and large-eddy simulation

Combustion Science and Technology

Volumn 176, Issue 5-6, 2004, Pages 851-865

  Molkov, V ^a   Makarov, D ^a   Grigorash, A ^a  

^a UNIVERSITY OF ULSTER   (United Kingdom)

Author keywords

Flame wrinkling; Hydrogen air premixed combustion; Large eddy simulation

Indexed keywords

COMBUSTION; COMPUTER SIMULATION; DIFFUSION; EXPLOSIONS; HYDRODYNAMICS; PRESSURE EFFECTS; STOICHIOMETRY; TURBULENCE; VELOCITY MEASUREMENT;

EXPLOSION FLAMES; FLAME WRINKLING; HYDROGEN/AIR PREMIXED COMBUSTION; LARGE-EDDY SIMULATION;

FLAMMABILITY;

EID: 2342446441     PISSN: 00102202     EISSN: None     Source Type: Journal    
DOI: 10.1080/00102200490428495     Document Type: Conference Paper

References (17)

1. Aung, K.T., Hassan, M.I., and Faeth, G.M. (1997) Flame stretch interactions of laminar premixed hydrogen/air flames at normal temperature and pressure. Combust. Flame, 109, 1.
2. 2 flames. Combust. Flame, 112, 1.
3. Bilger, R.W. (2000) Future progress in turbulent combustion research. Prog. Energy Combust. Sci., 26, 367.
4. Bradley, D. (1999) Instabilities and flame speeds in large-scale premixed gaseous explosions. Phil. Trans. R. Soc. Lond. A, 357, 3567.
5. Bradley, D., Cresswell, T.M., and Puttock, J.S. (2001) Flame acceleration due to flame-induced instabilities in large-scale explosions. Combust. Flame, 124, 551.
6. Clutter, J.K. and Luckritz, R.T. (2000) Comparison of reduced explosion model to blast curve and experimental data. J. Hazard. Mater., A79, 41.
7. Güider, Ö.L. (1990) Turbulent Premixed Combustion Modelling Using Fractal Geometry, Proc. Combust. Instit. 23, 835.
8. Güider, Ö.L., Smallwood, G.J., Wong, R., Snelling, D.R., Smith, R., Deschamps, B.M., and Sautet, J.-C. (2000) Flame front surface characteristics in turbulent premixed propane/air combustion. Combust. Flame, 120, 407.
9. Hawkes, E.R. and Cant, R.S. (2001) Implication of a flame surface density approach to large eddy simulation of premixed turbulent combustion. Combust. Flame, 126, 1617.
10. Khan, F.I. and Abbasi, S.A. (1999) Major accidents in process industries and an analysis of causes and consequences. J. Loss Prevent. Proc., 12, 361.
11. Kumar, R.K., Tamm, H., and Harrison, W.C. (1983) Combustion of hydrogen at high concentration including the effect of obstacles. Combust. Sci. and Technol., 35, 175.
12. Molkov, V., Dobashi, R., Suzuki, M., and Hirano, T. (1999) Modelling of vented hydrogen-air deflagrations and correlations for vent sizing. J. Loss Prevent. Proc., 12, 147.
13. Molkov, V., Dobashi, R., Suzuki, M., and Hirano, T. (2000) Venting of deflagrations: Hydrocarbon-air and hydrogen-air systems. J. Loss Prevent. Proc., 13, 397.
14. Oran, E.S. and Boris, J.P. (1987) Numerical Simulation of Reactive Flow, Elsevier, New York.
15. Poinsot, T. and Veynante, D. (2001) Theoretical and Numerical Combustion, Edwards, Philadelphia.
16. Vervisch, L. and Veynante, D. (2000) Interlinks Between Approaches for Modelling Turbulent Flames, Proc. Combust. Instit., 28, 175.
17. Yakhot, V. and Orszag, S. (1986) Renormalization group analysis of turbulence. I. Basic theory. J. Sci. Comput., 1, 3.