Nonlinear dynamic characteristics of self-excited thermoacoustic instabilities in premixed swirling flames

The nonlinear behavior of thermoacoustic oscillation for premixed swirl flames fueled with CH4/air mixtures is experimentally studied by changing the equivalence ratio phi, combustor inlet bulk velocity Uin and swirl number S. The nonlinear dynamic characteristics of the system are analyzed by the methods of phase space reconstruction, recurrence plot, Poincare ' section and 0-1 test for chaos. Five kinds of flame modes are observed in the combustion system with the change of phi, Uin, and S, which are lean/rich blow-off, stable combustion, quasiperiodic oscillation, and limit cycle oscillation. Subcritical Hopf bifurcation of the oscillation is captured either by changing phi or Uin, and phi and Uin are found to have similar effects on the flame mode transition under specific operating conditions. It is observed that the appearance of flame in the outer circulation zone (ORZ) and the enhancement of its burning intensity are matched with the occurrence of quasi-periodic and limit cycle oscillations, respectively. It is examined that the lean/rich blow-off limits and oscillation range are extended with a larger S, and the stable combustion regime is wider with a smaller S. This study contributes to understanding the nonlinear thermoacoustic instability of swirl flames under broad flame conditions, which helps to develop effective instability prediction and control methods in stable, efficient, and low-emission gas turbines.

Automated summary

The nonlinear behavior of thermoacoustic oscillation for premixed swirl flames fueled with CH4/air mixtures is experimentally studied. The study reveals the effects of changing equivalence ratio phi, combustor inlet bulk velocity Uin, and swirl number S on the flame modes and oscillations. The study also shows the relationship between the appearance of flame in the outer circulation zone and the occurrence of quasi-periodic and limit cycle oscillations. Furthermore, the study finds that the lean/rich blow-off limits and oscillation range are extended with a larger S, while the stable combustion regime is wider with a smaller S.