Experimental investigation of fast flame propagation in stratified hydrogen–air mixtures in semi-confined flat layers

• We study the flame propagation in semi-confined layers using stratified H2–air mixtures.
• Fast flames and detonation modes were experimentally observed.
• In fast flame propagation areas with low concentrations are involved in the process.
• Uniform mixtures with such concentrations will not reach this mode in the given geometry.

This paper presents results of an experimental investigation on fast flame propagation and the deflagration-to-detonation transition (DDT) and following detonation propagation in a semi-confined flat layer filled with stratified hydrogen–air mixtures. The experiments were performed in a transparent, rectangular channel open from below. The combustion channel has a width of 0.3 m and a length of 2.5 m. The effective layer thickness in the channel was varied by using different linear hydrogen concentration gradients. The method to create quasi-linear hydrogen concentration gradients that differ in the range and slope is also presented. The ignited mixtures were accelerated quickly to sonic flame speed in the first obstructed part of the channel. The interaction of the fast flame propagation with different obstacle set-ups was studied in the second part of the channel. The experimental results show an initiation of DDT by one additional metal grid in the obstructed semi-confined flat layer. Detonation propagation and failed detonation propagation were observed in obstructed and unobstructed parts of the channel.