Research on performance of \(H_{2}\) rich blowout limit in bluff-body burner (Q1954627)

Summary: In order to investigate \(H_{2}\) rich blowout limit at different blockage ratios and flow velocities, a CFD software FLUENT was used to simulate \(H_{2}\) burning flow field in bluff-body burner, and the software CHEMKIN was adopted to analyze the sensitivity of each elementary reaction. Composition Probability Density Function (C-PDF) model was adopted to simulate \(H_{2}\) combustion field in turbulence flame. The numerical results show that reactions R2 and R9 possess the largest positive and negative temperature sensitivity. Temperature has a very important influence on these two reactions. When equivalence ratio is 1, the mixture is most ignitable, and the critical ignition temperature is 1550 K. There should be an optimal blockage ratio which can stabilize the flame best. When the blockage ratio remains unchanged, the relationship between \(H_{2}\) RBL and flow velocity is a logarithmic function. When the flow velocity remains unchanged, the relationship between \(H_{2}\) RBL and blockage ratio is a parabolic function. A complete extinction requires three phases: the temperature sudden decline in the main stream, the energy dissipation from the recirculation zone to the main stream, and the complete extinction of the flame.