This study investigates flame stabilization and flashback in a trapped vortex combustor operating on a lean premixed hydrogen–air mixture at an equivalence ratio of ϕ = 0 . 35 . The combustor geometry features a U-bend in conjuction with a liner plate that aerodynamically stabilizes the flame. Particle Image Velocimetry (PIV) was used to study the (reacting) flow in detail at two Reynolds numbers: R e = 9 . 68 × 1 0 3 (case R-1, marginally stable flame) and R e = 13 . 55 × 1 0 3 (case R-2, highly stable flame). Within the U-bend, the flame front shows steady laminar-like behaviour where the velocity is primarily tangential to the flame front. Downstream of the U-bend, the shear layer weakens and the flame front becomes more intermittent. This intermittency may cause flame bulges to reach low-velocity zones near the U-bend wall, increasing the possibility of flame flashback through the boundary layer that wall. An analysis of the strain rate tensor shows that within the U-bend, the angle between the flame front normal and the most extensive strain rate direction remains close to 45°, indicating the dominance of shear straining in this region. Further downstream, alignment with the most extensive strain rate increases, indicating that combustion-induced expansion becomes more dominant. • Experimental study of hydrogen–air flames in a trapped vortex combustor. • Flame stabilization in the U-bend sustained by preferential diffusion effects. • Flashback shown to occur through the thick boundary layer along the U-bend wall.
Altenburg et al. (Sat,) studied this question.