Abstract
To explore the overpressure evolution laws and flame propagation characteristics in complex pipe networks after the addition of hydrogen to methane, we experimentally studied the explosive pressure wave and flame wave propagation laws for three different premixed gas mixtures with hydrogen-methane concentrations of 0, 10% and 20% when the equivalence ratio was 1. Experimental results indicate that the maximum explosion overpressure of the premixed gas increases with increasing distance from the explosion source, and it shows a gradually decreasing trend. In the complex pipe network, an overpressure zone is formed in the B–E–H and D–E sections of the network. The flame temperature is superimposed with the superimposition of the pressure, showing a trend of first increasing, then decreasing, then increasing, and finally decreasing in the complex pipe network. The flame arrival time increases with increasing distance, and the maximum flame speed shows a decreasing trend. The peak overpressure and maximum flame velocity of the premixed gas under a hydrogen volume fraction of 20% are 1.266 MPa and 168 m/s. The experimental research results could provide important theoretical guidelines for the prevention and control of fuel gas explosions in urban pipe networks.
Highlights
To explore the overpressure evolution laws and flame propagation characteristics in complex pipe networks after the addition of hydrogen to methane, we experimentally studied the explosive pressure wave and flame wave propagation laws for three different premixed gas mixtures with hydrogen-methane concentrations of 0, 10% and 20% when the equivalence ratio was 1
Okafor et al.[5] studied the propagation velocity of hydrogen-methane-air laminar premixed flames with different equivalent ratios and different volume fractions, and the results showed that under a certain equivalence ratio, the higher the hydrogen content in the mixture was, the faster the flame propagation speed
Emami et al.[15] mixed hydrogen and air in 90° curved pipes and three-way pipes to conduct experiments to study the explosion characteristics, and the results showed that the mixed gas weakened the peak overpressure and flame propagation speed of the explosion in the curved pipe and that the peak overpressure and flame propagation speed of the explosion in the three-way pipeline were not affected
Summary
To explore the overpressure evolution laws and flame propagation characteristics in complex pipe networks after the addition of hydrogen to methane, we experimentally studied the explosive pressure wave and flame wave propagation laws for three different premixed gas mixtures with hydrogen-methane concentrations of 0, 10% and 20% when the equivalence ratio was 1. Previous work on hydrogen-methane premixed gas explosions mainly focuses on the change characteristics of explosion overpressure and flame propagation velocity in straight pipes and simple structure pipelines.
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