Suppression of self-excited thermoacoustic instabilities by convective-acoustic interference

In this paper we demonstrate direct suppression of self-excited thermoacoustic instabilities over a range of operating conditions using targeted convective-acoustic interference. Premixed hydrogen enriched methane-air flames were confined in a cylindrical pipe resulting in self-excited instabilities that corresponded to the quarter wave mode of the pipe. To suppress the instability, the phenomenon of lock-in (synchronisation) between the acoustic mode and vortex shedding from a set of cylinders placed upstream was used to produce destructive interference and suppress the self-excited modes. This was done by varying the location of the cylinders to control the convective time-delay between the convective and acoustic modes so that their combined effect on the flame response was tuned to suppress the global fluctuation of the heat release rate. This leads to a reduction in the limit-cycle amplitude and stable operation without a significant change to the flame structure. Measurements were taken over a wide range of equivalence ratios to demonstrate that the method is capable of stabilising the system for all conditions. Using a methodology which relies on time-delays related to hydrodynamic instability, rather than flame-related parameters, enables its application to fuel-flexible systems, often designed to operate within a wide range of power outputs.