Premixed flame response to helical disturbances: Mean flame non-axisymmetry effects

Abstract: A key component of the thermoacoustic instability feedback mechanism is the excitation of hydrodynamic flow disturbances by narrowband acoustic fluctuations. In earlier work, we considered the response of time-averaged axisymmetric flames to helical disturbances. That study showed that although all helical modes cause local flame wrinkling, only the axisymmetric hydrodynamic mode, m = 0, contributes to the global heat release rate fluctuations. This paper extends this work to consider time-averaged flames that… Show more

“…1 Recently, the research on combustion instability is mainly focused on the lean-premixed combustion. 2–5 Although non-premixed flames are widely used in the industrial burners and boilers, combustion instabilities in those combustors are not well studied.…”

Study of burner geometry effects on non-premixed flame response under acoustic excitation

“…1 Recently, the research on combustion instability is mainly focused on the lean-premixed combustion. 2–5 Although non-premixed flames are widely used in the industrial burners and boilers, combustion instabilities in those combustors are not well studied.…”

Study of burner geometry effects on non-premixed flame response under acoustic excitation

“…When the unperturbed nominal flame is non-axisymmetric (i.e. m ξ 0 = 0), helical modes can excite a non-zero FTF as discussed in prior work (Acharya & Lieuwen 2016).…”

Nonlinear response of swirling premixed flames to helical flow disturbances

Models of the time-averaged heat release rate of the two-dimensional laminar premixed slit flame subjected to the transverse disturbance