Yan Z X. Catalytic mechanism studies on nano-aluminized propylene oxide fast reaction [D]. Chengdu: Sichuan University, 2006. (in Chinese)
[2]
炎正馨. 纳米铝粉在环氧丙烷快速反应催化机理研究 [D]. 成都: 四川大学, 2006.
[3]
Jones C Y, Nevers T J. Temperature-dependent distortions of the host structure of propylene oxide clathrate hydrate [J]. J Phys Chem, 2010, 114(9): 4194-4199.
[4]
Lifshitz A, Carmen T. Isomerization and decomposition of propylene oxide studies with single-pulse shock tube [J]. J Phys Chem, 1994, 98(43): 1161-1173.
[5]
Yan Z X, Hu D. Shock-induced thermal behavior of aluminum nano-particles in propylene oxide [J]. J Appl Phys, 2007, 249(5): 101-104.
[6]
Marinov N M, Westbrook C K, Pitz W J. Transport phenomena in combustion [J]. Combust Sci Tech, 1996, 24(3): 118-121.
[7]
Chen M, Bai C H, Liu Q M. Experimental research of deflagration to detonation transition of epoxypropane-aluminum- air mixtures in large-scale tube [J]. Chinese Journal of High Pressure Physics, 2011, 25(4): 359-364. (in Chinese)
Yan Z X, Guo C L, Chang L, et al. Thermal behaviors of aluminum nano-particles fast reaction with propylene oxide [J]. J Energetic Mater, 2008, 16(1): 5-8. (in Chinese)
Ono R, Nifuku M, Fujiwara S, et al. Minimum ignition energy of hydrogen-air mixture: Effects of humidity and spark duration [J]. J Electrostatics, 2007, 65(2): 87-93.
[14]
Oancea D, Razus D, Munteanu V, et al. High voltage and break spark ignition of propylene/air mixtures at various initial pressures [J]. J Loss Prev Process Ind, 2003, 16(5): 353-361.
[15]
Kindracki J, Kobiera A, Rarat G, et al. Influence of ignition position and obstacles on explosion development in methane-air mixture in closed vessels [J]. J Loss Prev Process Ind, 2007, 20(4-6): 551-561.
[16]
Randeberg E, Eckhoff R. Measurement of minimum ignition energies of dust clouds in the <1 mJ region [J]. J Hazard Mater, 2007, 140(1): 237-244.
[17]
Razus D, Brinzea V, Mitu M, et al. Inerting effect of the combustion products on the confined deflagration of liquefied petroleum gas-air mixtures [J]. J Loss Prev Process Ind, 2009, 22(4): 463-468.
[18]
Jones J C. Minimum ignition energies: A fundamental perspective [J]. J Loss Prev Process Ind, 2007, 20(2-4): 183.
[19]
Kurdyumov V, Blasco J, Sánchez A L, et al. On the calculation of the minimum ignition energy [J]. Combust Flame, 2004, 136(3): 394-397.
[20]
Lian P, Gao X, Mannan S. Prediction of minimum ignition energy of aerosols using flame kernel modeling combined with flame front [J]. J Loss Prev Process Ind, 2012, 25(1): 103-113.
[21]
Eckhoff R K, Ngo M, Olsen W. On the minimum ignition energy (MIE) for propane/air [J]. J Hazard Mater, 2010, 175(1-3): 293-297.
[22]
Ma Q J, Zhang Q, Pang L. Theoretical model of minimum ignition energy prediction for methane-air micture [J]. Chinese Journal of High Pressure Physics, 2012, 26(3): 301-305. (in Chinese)
Wang X Y, Hua J S, Wen S J. Experimental studies on Hugoniot data of methane-air mixtures under shock compression [J]. Chinese Journal of High Pressure Physics, 2009, 23(4): 315-320. (in Chinese)
