Experimental observations on the influence of hydrogen atoms diffusion on laminar and turbulent premixed burning velocities

Fuel

Volumn 189, Issue , 2017, Pages 66-78

  Burluka, A A ^a   Gaughan, R G ^b   Griffiths, J F ^a   Mandilas, C ^a   Sheppard, C G W ^a   Woolley, R ^c  

^a UNIVERSITY OF LEEDS   (United Kingdom)

^b EXXONMOBIL UPSTREAM RESEARCH COMPANY   (United States)

^c UNIVERSITY OF SHEFFIELD   (United Kingdom)

Author keywords

Burning velocity; Deuterium combustion; Hydrogen combustion; Isotope effect; Laminar flames; Turbulent flames

Indexed keywords

ATOMS; CARRIER MOBILITY; COMBUSTION; DEUTERIUM; HEXANE; HYDROGEN; ISOTOPES; PARAFFINS; TURBULENCE;

BURNING VELOCITY; HYDROGEN COMBUSTION; ISOTOPE EFFECT; LAMINAR FLAME; TURBULENT FLAME;

AIR;

EID: 84994631125     PISSN: 00162361     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.fuel.2016.10.088     Document Type: Article

References (50)

1. [1] Gu, X., Huang, Z., Wu, S., Laminar burning velocities and flame instabilities of butanol isomers–air mixtures. Combust Flame 157 (2010), 2318–2325.
2. [2] Wu, F., Kelley, A.P., Law, C.K., Laminar flame speeds of cyclohexane and mono-alkylated cyclohexanes at elevated pressures. Combust Flame 159 (2012), 1417–1425.
3. [3] Mehl, M., Herbinet, O., Dirrenberger, P., Bounaceur, R., Glaude, P.A., Battin-Leclerc, F., et al. Experimental and modeling study of burning velocities for alkyl aromatic components relevant to diesel fuels. Proc Combust Inst 35 (2015), 341–348.
4. [4] Farrell JT, Johnston RJ, Androulakis IP. Molecular structure effects on laminar burning velocities at elevated temperature and pressure. SAE tech paper 2004-01-2936; 2004.
5. [5] Beeckmann, J., Cai, L., Pitsch, H., Experimental investigation of the laminar burning velocities of methanol, ethanol, n-propanol and n-butanol at high pressure. Fuel 117 (2014), 340–350.
6. [6] Burluka, A.A., Gaughan, R.G., Griffiths, J.F., Mandilas, C., Sheppard, C.G.W., Woolley, R., Turbulent burning rates of gasoline components, Part 1 – effect of fuel structure of C6 hydrocarbons. Fuel 167 (2016), 347–356.
7. [7] Burluka, A.A., Gaughan, R.G., Griffiths, J.F., Mandilas, C., Sheppard, C.G.W., Woolley, R., Turbulent burning rates of gasoline components, Part 2 – effect of carbon number. Fuel 167 (2015), 357–365.
8. [8] Friedman, R., Burke, E., Burning velocities. Acetylene and dideutero-acetylene with air. Ind Eng Chem 43 (1951), 2772–2776.
9. [9] Buttini P, Corno C, Latella A, Prastaro M. Relevance of adding deuterated hydrocarbons to fuels in the autovehicular emissions studies. SAE paper 982622; 1998.
10. [10] Bradley, D., Lawes, M., Liu, K., Verhelst, S., Woolley, R., Laminar burning velocities of lean hydrogen–air mixtures at pressures up to 1.0 MPa. Combust Flame 149 (2007), 162–172.
11. [11] Hu, E., Huang, Z., He, J., Miao, H., Experimental and numerical study on laminar burning velocities and flame instabilities of hydrogen-air mixtures at elevated pressures and temperatures. Int J Hydrogen Energy 34 (2009), 8741–8755.
12. [12] Pareja, J., Burbano, H.J., Amell, A., Carvajal, J., Laminar burning velocities and flame stability analysis of hydrogen/air premixed flames at low pressure. Int J Hydrogen Energy 36 (2011), 6317–6324.
13. [13] Verhelst, S., Woolley, R., Lawes, M., Sierens, R., Laminar and unstable burning velocities and Markstein lengths of hydrogen-air mixtures at engine-like conditions. Proc Combust Inst 30 (2005), 209–216.
14. [14] Zamashchikov, V.V., Alekseev, V.A., Konnov, A.A., Laminar burning velocities of rich near-limiting flames of hydrogen. Int J Hydrogen Energy 39 (2014), 1874–1881.
15. [15] Dahoe, A.E., Laminar burning velocities of hydrogen–air mixtures from closed vessel gas explosions. J Loss Prev Process Ind 18 (2005), 152–166.
16. [16] Kido H, Nakahara M, Nakashima K, Kim J. Turbulent burning velocity of lean hydrogen mixtures. SAE technical paper 2003-01-1773; 2003.
17. [17] Kitagawa, T., Nakahara, T., Maruyana, K., Kado, K., Hayakawa, A., Kobyashi, S., Turbulent burning velocity of hydrogen–air premixed propagating flames at elevated pressures. Int J Hydrogen Energy 33 (2008), 5842–5849.
18. 2/air flames. Combust Flame 162 (2015), 4553–4565.
19. [19] Gray, P., Smith, D.B., Isotope effects on flame speeds for hydrogen and deuterium. Chem Commun (London), 1967, 146–148.
20. [20] Gray, P., Holland, S., Smith, D.B., The effect of isotopic substitution on the flame speeds of hydrogen-oxygen and hydrogen-nitrous oxide flames. Combust Flame 14 (1970), 361–374.
21. [21] Koroll, G.W., Kumar, R.K., Isotope effects on the combustion properties of deuterium and hydrogen. Combust Flame 84 (1991), 154–159.
22. [22] Gillespie L, Lawes M, Sheppard GGW, Woolley R. Aspects of laminar and turbulent burning velocity relevant to SI engines. SAE tech paper 2000-01-0192; 2000.
23. [23] Heywood, J.B., Internal combustion engine fundamentals. International ed., 1988, McGraw Hill ISBN 0071004998.
24. [24] Mandilas, C., Laminar and turbulent burning characteristics of hydrocarbon fuels. PhD thesis, 2008, University of Leeds.
25. [25] Bradley, D., Gaskel, P.H., Gu, X.J., Burning velocities, Markstein length, and flame quenching for spherical methane-air flames: a computational study. Combust Flame 104 (1996), 176–198.
26. [26] Bradley, D., Hicks, R.A., Lawes, M., Sheppard, C.G.W., Woolley, R., The measurement of laminar burning velocities and Markstein numbers for iso-octane–air and iso-octane–n-heptane–air mixtures at elevated temperatures and pressures in an explosion bomb. Combust Flame 115 (1998), 126–144.
27. 2 mixtures using the spherical bomb method. In: 2nd Mediterranean comb symp, Exp Therm Fluid Sci, vol. 27; 2003. p. 385–93.
28. [28] Jerzembeck S, Peters N. Laminar spherical flame kernel investigation of very rich premixed hydrocarbon-air mixtures in a closed vessel under microgravity conditions. SAE tech paper 2008-01-0471; 2008.
29. 2 dilution. Energy Fuels 23 (2009), 735–739.
30. [30] Varea, E., Modica, V., Vandel, A., Renou, B., Measurement of laminar burning velocity and Markstein length relative to fresh gases using a new post-processing procedure. Application to laminar spherical flames for methane, ethanol and isooctane/air mixtures. Combust Flame 159 (2012), 577–590.
31. [31] Moghaddas, A., Eisazadeh-Far, K., Metghalchi, H., Laminar burning speed measurement of premixed n-decane/air mixtures using spherically expanding flames at high temperatures and pressures. Combust Flame 159 (2012), 1437–1443.
32. [32] Lawes, M., Ormsby, M.P., Sheppard, C.G.W., Woolley, R., Variation of turbulent burning rate of methane, methanol and isooctane air mixtures with equivalence ratio at elevated pressure. Combust Sci Technol 177 (2005), 1273–1289.
33. [33] Abdi Aghdam E, Burluka AA, Hattrell T, Liu K, Sheppard CGW, Neumeister J, et al. Study of cyclic variation in an SI engine using quasi-dimensional combustion model. SAE paper 2007-01-0939; 2007.
34. [34] Law CK. Dynamics of stretched flames. In: 22nd Symp int combust, vol. 22; 1988. p. 1381–402.
35. [35] Bradley, D., Sheppard, C.G.W., Woolley, R., Greenhalgh, D.A., Lockett, R.D., The development and structure of flame instabilities and cellularity at low Markstein numbers in explosions. Combust Flame 122 (2000), 195–209.
36. [36] Bradley, D., Lung, F.K., Spark ignition and the early stages of turbulent flame propagation. Combust Flame 69 (1987), 71–93.
37. [37] Abdel-Gayed, R.G., Bradley, D., Lawes, M., Turbulent burning velocities: a general correlation in terms of straining rates. Proc R Soc London A414 (1987), 389–413.
38. [38] Jomaas, G., Law, C.K., Bechtold, J.K., On transition to cellularity in expanding spherical flames. J Fluid Mech 583 (2007), 1–26.
39. [39] Bird, R.B., Stewart, W.E., Lightfoot, E.N., Transport phenomena. 2nd ed., 2002, Wiley & Sons ISBN 0471410772.
40. [40] Wilke, C.R., A viscosity equation for gas mixtures. J Chem Phys 18 (1950), 517–519.
41. [41] Gaughan R. Private communication. University of Leeds; 2008.
42. [42] < http://webbook.nist.gov/chemistry/> [accessed 05/2016].
43. [43] Borghi, R., Turbulent combustion modeling. Progr Energy Combust 14 (1988), 245–292.
44. [44] Zimont VL. To computations of turbulent combustion of partially premixed gases, chemical physics of combustion and explosion processes. Combustion of multi-phase and gas systems. OIKhF, Chernogolovka; 1977. p. 77–80 [in Russian].
45. [45] Lipatnikov, A.N., Chomiak, J., Turbulent flame speed and thickness: phenomenology, evaluation, and application in multi-dimensional simulations. Progr Energy Combust Sci 28 (2002), 1–74.
46. [46] < http://garfield.chem.elte.hu/Burcat/burcat.html> [accessed 05/2016].
47. [47] Marinov, N.M., Curran, H.J., Pitz, W.J., Westbrook, C.K., Chemical kinetic modeling of hydrogen under conditions found in internal combustion engines. Energy Fuels 12 (1998), 78–82.
48. 2/air flames: chemical kinetics and molecular diffusion effects. Combust Flame 142 (2005), 374–387.
49. 2O. J Chem Phys 76 (1982), 311–315.
50. [50] Glassman, I., Combustion. 3rd ed., 1996, Academic Press ISBN 0122858522.