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Mitigation of thermoacoustic instabilities via porous plugs
Article
Authorship:
Gatón-Pérez, Pedro ; BRAUN, MATIAS NICOLAS ; Prasad Choudhury, Siba ; Muntean, Victor ; Martínez-Ruiz, DanielDate:
2025Publishing House and Editing Place:
CAMBRIDGE UNIV PRESSMagazine:
JOURNAL OF FLUID MECHANICS, vol. 1013 CAMBRIDGE UNIV PRESSSummary *
The interaction between the dynamics of a flame front and the acoustic field within a combustion chamber represents an aerothermochemical problem with the potential to generate hazardous instabilities, which limit burner performance by constraining design and operational parameters. The experimental configuration described here involves a laminar premixed flame burning in an open–closed slender tube, which can also be studied through simplified modelling. The constructive coupling of the chamber acoustic modes with the flame front can be affected via strategic placement of porous plugs, which serve to dissipate thermoacoustic instabilities. These plugs are lattice-based, 3-D-printed using low-force stereolithography, allowing for complex geometries and optimal material properties. A series of porous plugs was tested, with variations in their porous density and location, in order to assess the effects of these variables on viscous dissipation and acoustic eigenmode variation. Pressure transducers and high-speed cameras are used to measure oscillations of a stoichiometric methane–air flame ignited at the tube’s open end. The findings indicate that the porous medium is effective in dissipating both pressure amplitude and flame-front oscillations, contingent on the position of the plug. Specifically, the theoretical fluid mechanics model is developed to calculate frequency shifts and energy dissipation as a function of plug properties and positioning. The theoretical predictions show a high degree of agreement with the experimental results, thereby indicating the potential of the model for the design of dissipators of this nature and highlighting the first-order interactions of acoustics, viscous flow in porous media and heat transfer processes. Information provided by the agent in SIGEVAKey Words
POROUS PLUGSADDITIVE MANUFACTURING MITIGATIONCOMBUSTION