Experimental study and three-dimensional simulation of premixed hydrogen/air flame propagation in a closed duct

International Journal of Hydrogen Energy

Volumn 37, Issue 15, 2012, Pages 11466-11473

  Xiao, Huahua ^a   Shen, Xiaobo ^a   Sun, Jinhua ^a  

^a UNIVERSITY OF SCIENCE AND TECHNOLOGY OF CHINA   (China)

Author keywords

Hydrogen air mixture; Premixed flame; Schlieren; Thickened flame; Tulip flame

Indexed keywords

COMBUSTION DYNAMICS; EXPERIMENTAL STUDIES; FLAME DYNAMICS; FLAME MODELS; FLAME PROPAGATION; FLAME SHAPES; FLAME SPEED; FLAME WRINKLING; HIGH-SPEED; NUMERICAL STUDIES; PREMIXED; PREMIXED COMBUSTION; PREMIXED FLAME; PRESSURE DYNAMICS; PRESSURE GROWTH; PRESSURE TRANSIENT; PRESSURE WAVES; SCHLIEREN; SCHLIEREN PHOTOGRAPHY; THICKENED FLAME; THREE DIMENSIONAL SIMULATIONS; TULIP FLAME;

COMPUTER SIMULATION; DUCTS; DYNAMICS; EXPERIMENTS; FLAMMABILITY;

COMBUSTION;

EID: 84863622847     PISSN: 03603199     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijhydene.2012.05.006     Document Type: Article

References (47)

1. R. Starke, and P. Roth An experimental investigation of flame behavior during cylindrical vessel explosions Combust Flame 66 1986 249 259
2. G.M. Abu-Orf, and R.S. Cant A turbulent reaction rate model for premixed turbulent combustion in spark-ignition engines Combust Flame 122 2000 233 252
3. L. Kagan, and G. Sivashinsky The transition from deflagration to detonation in thin channels Combust Flame 134 2003 389 397
4. S.B. Dorofeev Hydrogen flames in tubes: critical run-up distances Int J Hydrogen Energy 34 2009 5832 5837
5. S.B. Dorofeev Flame acceleration and explosion safety applications Proc Combust Inst 33 2011 2161 2175
6. S.B. Dorofeev, M.S. Kuznetsov, V.I. Alekseev, A.A. Efimenko, and W. Breitung Evaluation of limits for effective flame acceleration in hydrogen mixtures J Loss Prevent Proc. 14 2001 583 589
7. V.V. Bychkov, and M.A. Liberman Dynamics and stability of premixed flames Phys Rep 325 2000 116 237
8. D. Razus, C. Movileanu, V. Brinzea, and D. Oancea Explosion pressures of hydrocarbon-air mixtures in closed vessels J Hazard Mater 135 2006 58 65
9. T. Huld, G. Peter, and H. Stadtke Numerical simulation of explosion phenomena in industrial environments J Hazard Mater 46 1996 185 195
10. V. Akkerman, V. Bychkov, A. Petchenko, and L.E. Eriksson Accelerating flames in cylindrical tubes with nonslip at the walls Combust Flame 145 2006 206 219
11. T. Kratzel, E. Pantow, and M. Fischer On the transition from a highly turbulent curved flame into a tulip flame Int J Hydrogen Energy 23 1998 45 51
12. C.K. Law Combustion physics 2006 Cambridge university press New York
13. M. Matalon Flame dynamics Proc Combust Inst 32 2009 57 82
14. D. Dunn-Rankin, and R.F. Sawyer Tulip flames: changes in shape of premixed flames propagating in closed tubes Exp Fluids 24 1998 130 140
15. M. Gonzalez Acoustic instability of a premixed flame propagating in a tube Combust Flame 107 1996 245 259
16. P. Metzener, and M. Matalon Premixed flames in closed cylindrical tubes Combust Theor Model 5 2001 463 483
17. V. Di Sarli, A. Di Benedetto, and G. Russo Using Large Eddy Simulation for understanding vented gas explosions in the presence of obstacles J Hazard Mater 169 2009 435 442
18. V. Di Sarli, A. Di Benedetto, and G. Russo Sub-grid scale combustion models for large eddy simulation of unsteady premixed flame propagation around obstacles J Hazard Mater 180 2010 71 78
19. V.N. Gamezo, T. Ogawa, and E.S. Oran Flame acceleration and DDT in channels with obstacles: effect of obstacle spacing Combust Flame 155 2008 302 315
20. G. Ciccarelli, and S. Dorofeev Flame acceleration and transition to detonation in ducts Prog Energy Combust 34 2008 499 550
21. O.C. dC. Ellis Flame movement in gaseous explosive mixtures Fuel 7 1928 502 508
22. H. Guenoche Flame propagation in tubes and in closed vessels G.H. Markstein, Nonsteady flame propagation 1964 Pergamon Press New York 107
23. F.S. Marra, and G. Continillo Numerical study of premixed laminar flame propagation in a closed tube with a full Navier-Stokes approach Proc Combust Inst 26 1996 907 913
24. J.W. Dold, and G. Joulin An evolution equation modeling inversion of tulip flames Combust Flame 100 1995 450 456
25. M. Gonzalez, R. Borghi, and A. Saouab Interaction of a flame front with its self-generated flow in an enclosure-the tulip flame phenomenon Combust Flame 88 1992 201 220
26. M. Matalon, and J.L. Mcgreevy The initial development of a tulip flame Proc Combust Inst 1994 1407 1413
27. B. Nkonga, G. Fernandez, H. Guillard, and B. Larrouturou Numerical investigations of the tulip flame instability-comparisons with experimental results Combust Sci Technol 87 1993 69 89
28. A.K. Kaltayev, U.R. Riedel, and J. Warnatz The hydrodynamic structure of a methane-air tulip flame Combust Sci Technol 158 2000 53 69
29. M. Matalon, and P. Metzener The propagation of premixed flames in closed tubes J Fluid Mech 336 1997 331 350
30. C. Clanet, and G. Searby On the 'tulip flame' phenomenon Combust Flame 105 1996 225 238
31. V. Bychkov, V. Akkerman, G. Fru, A. Petchenko, and L.E. Eriksson Flame acceleration in the early stages of burning in tubes Combust Flame 150 2007 263 276
32. K.T. Aung, M.I. Hassan, and G.M. Faeth Flame stretch interactions of laminar premixed hydrogen/air flames at normal temperature and pressure Combust Flame 109 1997 1 24
33. T. Poinsot, and D. Veynante Theoretical and numerical combustion 2nd ed. 2005 Edwards RT Inc Philadelphia
34. A.E. Dahoe Laminar burning velocities of hydrogen-air mixtures from closed vessel gas explosions J Loss Prevent Proc 18 2005 152 166
35. D. Baraldi, A. Kotchourko, A. Lelyakin, J. Yanez, A. Gavrikov, and A. Efimenko An inter-comparison exercise on CFD model capabilities to simulate hydrogen deflagrations with pressure relief vents Int J Hydrogen Energy 35 2010 12381 12390
36. D. Baraldi, A. Kotchourko, A. Lelyakin, J. Yanez, P. Middha, and O.R. Hansen An inter-comparison exercise on CFD model capabilities to simulate hydrogen deflagrations in a tunnel Int J Hydrogen Energy 34 2009 7862 7872
37. V. Molkov A multiphenomena turbulent burning velocity model for large eddy simulation of premixed combustion G.D. Roy, Nonequilibrium phenomena: plasma, combustion, atmosphere 2009 Torus Press Ltd. Moscow 315 323
38. V. Molkov, D. Makarov, and J. Puttock The nature and large eddy simulation of coherent deflagrations in a vented enclosure-atmosphere system J Loss Prevent Proc 19 2006 121 129
39. V.V. Molkov, D.V. Makarov, and H. Schneider Hydrogen-air deflagrations in open atmosphere: large eddy simulation analysis of experimental data Int J Hydrogen Energy 32 2007 2198 2205
40. H.D. Ng, and J.H.S. Lee Comments on explosion problems for hydrogen safety J Loss Prevent Proc 21 2008 136 146
41. Legier JP, Poinsot T, Veynante D. Dynamically thickened flame LES model for premixed and non-premixed turbulent combustion. Proceedings of the Summer Program; 2000.
42. T.D. Butler A numerical method for two-dimensional unsteady reacting flows Proc Combust Inst 16 1977 1503
43. K.K. Kuo Principles of combustion 2nd ed. 2005 John Wiley & Sons Inc
44. O. Colin, F. Ducros, D. Veynante, and T. Poinsot A thickened flame model for large eddy simulations of turbulent premixed combustion Phys Fluids 12 2000 1843 1863
45. G. Lacaze, B. Cuenot, T. Poinsot, and M. Oschwald Large eddy simulation of laser ignition and compressible reacting flow in a rocket-like configuration Combust Flame 156 2009 1166 1180
46. A. De, and S. Acharya Large eddy simulation of a premixed Bunsen flame using a modified thickened-flame model at two Reynolds number Combust Sci Technol 181 2009 1231 1272
47. V. Molkov, D. Makarov, and A. Grigorash Cellular structure of explosion flames: modeling and large-eddy simulation Combust Sci Technol 176 2004 851 865