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Abstract
To research the characteristics of vented explosion of methane-air mixture in the pipeline, coal mine tunnel or other closed space, the experiments and numerical simulations were carried out. In this work, explosion characteristics and flame propagation characteristics of methane in pipeline and coal mine tunnel are studied by using an explosion test system, combined with FLACS software, under different vented conditions. The numerical simulation results of methane explosion are basically consistent with the physical experiment results, which indicates that the numerical simulation for methane explosion is reliable to be applied to the practice. The results show that explosion parameters (pressure, temperature and product concentration) of methane at five volume fractions have the same change trend. Nevertheless, the explosion intension of 10.0% methane is the largest and that of 9.5% methane is relatively weak, followed by 11.0% methane, 8.0% methane and 7.0% methane respectively. Under different vented conditions, the pressure and temperature of methane explosion are the highest in the pipeline without a vent, followed by the pipeline where ignition or vent position is in each end, and those are the lowest in the pipeline with ignition and vent at the same end. There is no significant effect on final product concentration of methane explosion under three vented conditions. For coal mine tunnel, it is indicated that the maximum explosion pressure at the airproof wall in return airway with the branch roadway at 50 m from goaf is significantly decreased while that in intake airway does not change overwhelmingly. In addition, when the branch roadway is longer or its section is larger, the peak pressure of airproof wall reduces slightly.
Keywords
methane-air
/
flame propagation
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CFD simulation
/
vented explosion
/
ignition position
/
peak pressure
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Bin Su, Zhen-min Luo, Tao Wang, Lang Liu.
Experimental and numerical evaluations on characteristics of vented methane explosion.
Journal of Central South University, 2020, 27(8): 2382-2393 DOI:10.1007/s11771-020-4456-1
| [1] |
LuoZ, SuB, LiQ, WangT, KangX, ChengF, GaoS, LiuL. Micromechanism of the initiation of a multiple flammable gas explosion [J]. Energy & Fuels, 2019, 33: 7738-7748
|
| [2] |
SU B, LUO Z, WANG T, XIE C, CHENG F. Chemical kinetic behaviors at the chain initiation stage of CH4/H2/air mixture [J]. Journal of Hazardous Materials, 2020. DOI: https://doi.org/10.1016/j.jhazmat.2020.123680.
|
| [3] |
SuB, LuoZ, WangT, YanK, ChengF, DengJ. Coupling analysis of the flame emission spectra and explosion characteristics of CH4/C2H6/Air mixtures [J]. Energy & Fuels, 2020, 34: 920-928
|
| [4] |
LuoZ, HaoQ, WangT, LiR, ChengF, DengJ. Experimental study on the deflagration characteristics of methane-ethane mixtures in a closed duct [J]. Fuel, 2020, 259: 1-10
|
| [5] |
SuB, LuoZ, WangT, ZhangJ, ChengF. Experimental and principal component analysis studies on minimum oxygen concentration of methane explosion [J]. International Journal of Hydrogen Energy, 2020, 45(21): 12225-12235
|
| [6] |
LuoZ, LiD, SuB, ZhangS, DengJ. On the time coupling analysis of explosion pressure and intermediate generation for multiple flammable gases [J]. Energy, 2020, 198: 1-10
|
| [7] |
FerraraG, BenedettoA, SalzanoE, SalzanoE, RussoG. CFD analysis of gas explosions vented through relief pipes [J]. Journal of Hazardous Materials, 2006, 137(2): 654-665
|
| [8] |
ProustC, LepretteE. The dynamics of vented gas explosions [J]. Process Safety Progress, 2010, 29(3): 231-235
|
| [9] |
BauwensC R, ChaffeeJ, DorofeevS B. Vented explosion overpressures from combustion of hydrogen and hydrocarbon mixtures [J]. International Journal of Hydrogen Energy, 2011, 36(3): 2329-2336
|
| [10] |
WangZ, PanM, WangS, SunD. Effects on external pressures caused by vented explosion of methane-air mixtures in single and connected vessels [J]. Process Safety Progress, 2015, 33(4): 385-391
|
| [11] |
GuoJ, LiQ, ChenD, HuK, ShaoK, GuoC, WangC. Effect of burst pressure on vented hydrogen-air explosion in a cylindrical vessel [J]. International Journal of Hydrogen Energy, 2015, 40(19): 6478-6486
|
| [12] |
KunduS, ZanganehJ, EschebachD, MahinpeyN, MoghtaderiB. Explosion characteristics of methane-air mixtures in a spherical vessel connected with a duct [J]. Process Safety & Environmental Protection, 2017, 111: 85-93
|
| [13] |
CaoY, LiB, GaoK. Pressure characteristics during vented explosion of ethylene-air mixtures in a square vessel [J]. Energy, 2018, 151: 26-32
|
| [14] |
SunS, QiuY, XingH, WangM. Effects of concentration and initial turbulence on the vented explosion characteristics of methane-air mixtures [J]. Fuel, 2020, 267: 1-9
|
| [15] |
MokhtarK, KasmaniR, HassanC, HamidM, EmamiS, NorM. Reliability and applicability of empirical equations in predicting the reduced explosion pressure of vented gas explosions [J]. Journal of Loss Prevention in the Process Industries, 2020, 63: 1-10
|
| [16] |
ZhangY, JiaoF, HuangQ, CaoW, ShiL, ZhaoM, YuC, NieB, CaoX. Experimental and numerical studies on the closed and vented explosion behaviors of premixed methane-hydrogen/air mixtures [J]. Applied Thermal Engineering, 2019, 159: 1-11
|
| [17] |
WanS, YuM, ZhengK, WangC, YuanZ, YangX. Effect of side vent size on a methane/air explosion in an end-vented duct containing an obstacle [J]. Experimental Thermal and Fluid Science, 2019, 101: 141-150
|
| [18] |
PhylaktouH, AndrewsG E. Gas explosions in long closed vessels [J]. Combustion Science & Technology, 1991, 77(1–3): 27-39
|
| [19] |
IndrackiJ, KobieraA, RarataG, WolanskiP. Influence of ignition position and obstacles on explosion development in methane-air mixture in closed vessels [J]. Journal of Loss Prevention in the Process Industries, 2007, 20(4–6): 551-561
|
| [20] |
WillacyS K, PhylaktouH N, AndrewsG E, FerraraG. Stratified propane-air explosions in a duct vented geometry: Effect of concentration, ignition and injection position [J]. Process Safety & Environmental Protection, 2007, 85(2): 153-161
|
| [21] |
GuoJ, SunX, RuiS, CaoY, HuK, WangC. Effect of ignition position on vented hydrogen-air explosions [J]. International Journal of Hydrogen Energy, 2016, 40(45): 15780-15788
|
| [22] |
TomlinG, JohnsonD M, CroninP, PhylaktouH, AndrewsG. 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
|
| [23] |
QiS, DuY, WangS, ZhouY, LiG. 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
|
| [24] |
BatraevI S, Vasil’evA A, Ul’YanitskiiV Y, ShtertserA A, RybinD K. Investigation of gas detonation in over-rich mixtures of hydrocarbons with oxygen [J]. Combustion Explosion & Shock Waves, 2018, 54(2): 207-215
|
| [25] |
ZhangK, WangZ, ChenZ, JiangF, WangS. Influential factors of vented explosion position on maximum explosion overpressure of methane-air mixture explosion in single spherical container and linked vessels [J]. Process Safety Progress, 2018, 37(2): 248-255
|
| [26] |
SinhaA, WenJ. A simple model for calculating peak pressure in vented explosions of hydrogen and hydrocarbons [J]. International Journal of Hydrogen Energy, 2019, 44(40): 22719-22732
|
| [27] |
NIE B, HE X, WANG C, LU H, XUE F. Computational method of the propagation velocity of methane explosion flame based on correlation coefficient of images [J]. Combustion Science and Technology, 2015. DOI: https://doi.org/10.1080/00102202.2015.1019621.
|
| [28] |
AmyotteP R, PatilS, PeggM J. Confined and vented ethylene/air deflagrations at initially elevated pressures and turbulence levels [J]. Process Safety & Environmental Protection, 2002, 80(2): 71-77
|
| [29] |
ZhangK, WangZ, GongJ, LiuM, DouZ, JiangJ. Experimental study of effects of ignition position, initial pressure and pipe length on H2-air explosion in linked vessels [J]. Journal of Loss Prevention in the Process Industries, 2017, 50: 1-6
|
| [30] |
JiangB, LinB, ShiS, ZhuC, LiuQ, ZhaiC. A numerical simulation of the influence initial temperature has on the propagation characteristics of, and safe distance from, a gas explosion [J]. International Journal of Mining Science and Technology, 2012, 22(3): 307-310
|
| [31] |
WeiH, XuZ, ZhouL, GaoD, ZhaoJ. Effect of initial pressure on flame-shock interaction of hydrogen-air premixed flames [J]. International Journal of Hydrogen Energy, 2017, 42(17): 12657-12668
|
| [32] |
WenX, YuM, JiW, YueM, ChenJ. Methane-air explosion characteristics with different obstacle configurations [J]. International Journal of Mining Science and Technology, 2015, 25(2): 213-218
|
| [33] |
LiH, GuoJ, TangZ, LiJ, HuangP, ZhangS. Effects of ignition, obstacle, and side vent locations on vented hydrogen-air explosions in an obstructed duct [J]. International Journal of Hydrogen Energy, 2019, 44(36): 20598-20605
|
| [34] |
VyazminaE, JallaisS. Validation and recommendations for FLACS CFD and engineering approaches to model hydrogen vented explosions: Effects of concentration, obstruction vent area and ignition position [J]. International Journal of Hydrogen Energy, 2016, 41(33): 15101-15109
|
| [35] |
BaoQ, FangQ, ZhangY, ChenL, YangS, LiZ. Effects of gas concentration and venting pressure on overpressure transients during vented explosion of methane-air mixtures [J]. Fuel, 2016, 175: 40-48
|
