[1] BAO Q, FANG Q,ZHANG Y,et al. Effects of gas concentration and venting pressure on overpressure transients during vented explosion of methane-air mixtures[J]. Fuel,2016,175:40-48.
[2] 丁宇奇,刘巨保,刘健壮,等. 立式拱顶储罐抗压环结构与弱顶性能分析[J]. 石油化工设备,2012,41(5):24-28. DING Y Q,LIU J B,LIU J Z,et al. Compression ring structure of vertical vault-roof tank and weak roof performance analysis[J]. Petro-Chemical Equipment,2012,41(5):24-28.
[3] CUI Y Y,WANG Z R,MA L S,et al. Influential factors of gas explosion venting in linked vessels[J]. Journal of Loss Prevention in the Process Industries,2017,46:108-114.
[4] LI Z,CHEN L,FANG Q,et al. Experimental and numerical study of unreinforced clay brick masonry walls subjected to vented gas explosions[J]. International Journal of Impact Engineering,2017,104:107-126.
[5] TASCON A. Design of silos for dust explosions:determination of vent area sizes and explosion pressures[J]. Engineering Structures,2017,134:1-10.
[6] GAO W,YU J,LI J,et al. Experimental investigation on micro-and nano-PMMA dust explosion venting at elevated static activation overpressures[J]. Powder Technology,2016,301:713-722.
[7] GUO J,WANG C,LIU X. Experimental study on duct-vented explosion of hydrogen-air mixtures in a wide range of equivalence ratio[J]. Industrial & Engineering Chemistry Research,2016,55(35):9518-9523.
[8] SHAO H,JIANG S,WU Z,et al. Application and effect of negative pressure chambers on pipeline explosion venting[J]. Journal of Loss Prevention in the Process Industries,2016,41:8-17.
[9] UGARTE O J,AKKERMAN V Y,RANGWALA A S. A computational platform for gas explosion venting[J]. Process Safety and Environmental Protection,2016,99:167-174.
[10] CHAO J,DOROFEEV S B. Evaluating the overall efficiency of a flameless venting device for dust explosions[J]. Journal of Loss Prevention in the Process Industries,2015,36:63-71.
[11] FAKANDU B M,ANDREWS G E,PHYLAKTOU H N. Vent burst pressure effects on vented gas explosion reduced pressure[J]. Journal of Loss Prevention in the Process Industries,2015,36:429-438.
[12] GUO J,LI Q,CHEN D,et al. Effect of burst pressure on vented hydrogen-air explosion in a cylindrical vessel[J]. International Journal of Hydrogen Energy,2015,40(19):6478-6486.
[13] KUZNETSOV M,FRIEDRICH A,STERN G,et al. Medium-scale experiments on vented hydrogen deflagration[J]. Journal of Loss Prevention in the Process Industries,2015,36:416-428.
[14] MOLKOV V,BRAGIN M. Hydrogen-air deflagrations:vent sizing correlation for low-strength equipment and buildings[J]. International Journal of Hydrogen Energy,2015,40(2):1256-1266.
[15] TOMLIN G,JOHNSON D M,CRONIN P,et al. The effect of vent size and congestion in large-scale vented natural gas/air explosions[J]. Journal of Loss Prevention in the Process Industries,2015,35:169-181.
[16] YAN X,YU J,GAO W. Flame behaviors and pressure characteristics of vented dust explosions at elevated static activation overpressures[J]. Journal of Loss Prevention in the Process Industries,2015,33:101-108.
[17] BAUWENS C R,DOROFEEV S B. Effect of initial turbulence on vented explosion overpressures from lean hydrogen-air deflagrations[J]. International Journal of Hydrogen Energy,2014,39(35):20509-20515.
[18] MA Q,ZHANG Q,PANG L,et al. Effects of hydrogen addition on the confined and vented explosion behavior of methane in air[J]. Journal of Loss Prevention in the Process Industries,2014,27:65-73.
[19] ROCOURT X,AWAMAT S,SOCHET I,et al. Vented hydrogen-air deflagration in a small enclosed volume[J]. International Journal of Hydrogen Energy,2014,39(35):20462-20466.
[20] KASMANI R M,ANDREWS G E,PHYLAKTOU H N. Experimental study on vented gas explosion in a cylindrical vessel with a vent duct[J]. Process Safety and Environmental Protection,2013,91(4):245-252.
[21] PEDERSEN H H,TOMLIN G,MIDDHA P,et al. Modelling large-scale vented gas explosions in a twin-compartment enclosure[J]. Journal of Loss Prevention in the Process Industries,2013,26(6):1604-1615.
[22] QUILLATRE P,VERMOREL O,POINSOT T,et al. Large eddy simulation of vented deflagration[J]. Industrial & Engineering Chemistry Research,2013,52(33):11414-11423.
[23] FAKANDU B M K R. The venting of hydrogen-air explosions in an enclosure with L/D=2.8[C]//Proc. Ninth International Symposium on Hazardous Process Materials and Industrial Explosions(Ⅸ ISHPMIE),Krakow,2012.
[24] CHAO J,BAUWENS C R,DOROFEEV S B. An analysis of peak overpressures in vented gaseous explosions[J]. Proceedings of the Combustion Institute,2011,33(2):2367-2374.
[25] FELDGUN V R,KARINSKI Y S,YANKELEVSKY D Z. A simplified model with lumped parameters for explosion venting simulation[J]. International Journal of Impact Engineering,2011,38(12):964-975.
[26] LOWESMITH B J,MUMBY C,HANKINSON G,et al. Vented confined explosions involving methane/hydrogen mixtures[J]. International Journal of Hydrogen Energy,2011,36(3):2337-2343.
[27] GUO J,SUN X,RUI S,et al. Effect of ignition position on vented hydrogen-air explosions[J]. International Journal of Hydrogen Energy,2015,40(45):15780-15788.
[28] BAUWENS C R. Effect of ignition location,vent size,and obstacles on vented explosion overpressures in propane-air mixtures[J]. Combustion Science and Technology,2010,182:1915-1932.
[29] QI S,DU Y,WANG S,et al. The effect of vent size and concentration in vented gasoline-air explosions[J]. Journal of Loss Prevention in the Process Industries,2016,44:88-94.
[30] 王世茂,杜扬,李国庆,等. 局部开口受限空间油气爆燃的超压瞬变与火焰行为[J]. 化工学报,2017,68(8):3310-3318. WANG S M,DU Y,LI G Q,et al. Overpressure transients and flame behaviors of gasoline-air mixture deflagration in confined space with local opening[J]. CIESC Journal,2017,68(8):3310-3318.
[31] 杜扬,王世茂,齐圣,等. 油气在顶部含弱约束结构受限空间内的爆炸特性[J]. 爆炸与冲击,2017,37(1):53-60. DU Y,WANG S M,QI S,et al,Explosion of gasoline/air mixture in confined space with weakly constrained structure at the top[J]. Explosion and Shock Wave,2017,37(1):53-60. |